Your search keyword '"Wei-Bin, Shen"' showing total 48 results

1. Functional cargos of exosomes derived from Flk-1+ vascular progenitors enable neurulation and ameliorate embryonic anomalies in diabetic pregnancy

Author

Songying Cao, Yanqing Wu, E. Albert Reece, Cheng Xu, Wei-Bin Shen, Sunjay Kaushal, and Peixin Yang

Subjects

Biology (General), QH301-705.5

Abstract

A crosstalk among components of the endoderm, mesoderm and neuroectoderm via the growth factor FGF2 and Survivin-containing exosomes is essential for successful neurulation and is deregulated in diabetic pregnancy.

Published

2022

2. Obesity impacts placental function through activation of p-IRE1a-XBP1s signaling

Author

Wei-Bin Shen, Bingbing Wang, Ruofan Yao, Katherine R. Goetzinger, Sheng Wu, Haijun Gao, and Peixin Yang

Subjects

placenta, maternal obese, endoplasmic reticulum stress, IRE1α, XBP1S, chaperones, Biology (General), QH301-705.5

Abstract

Maternal obesity is associated with a variety of obstetrical outcomes including stillbirth, preeclampsia, and gestational diabetes, and increases the risk of fetuses for congenital heart defects. Obesity during pregnancy represents a major contribution to metabolic dysregulation, which not only plays a key role in the pathogenesis of adverse outcome but also can potently induce endoplasmic reticulum (ER) stress. However, the mechanism associating such an obesogenic metabolic environment and adverse pregnancy outcomes has remained poorly understood. In this study, we aimed to determine whether the ER stress pathways (also named unfolded protein response (UPR)) were activated in the placenta by obesity. We collected placenta from the obese pregnancy (n = 12) and non-obese pregnancy (n = 12) following delivery by Caesarean-section at term. The specimens were assessed with immunocytochemistry staining and RT-QPCR. Our results revealed that in the obese placenta, p-IRE1α and XBP1s were significantly increased, CHOP and nine UPR chaperone genes were upregulated, including GRP95, PDIA6, Calnexin, p58IPK, SIL-1, EDEM, Herp, GRP58 and Calreticulin. However, Perk and BiP are not activated in the obese placenta. Our data suggest that upregulated p-IRE1α and XBP1s signaling, and UPR chaperone genes may play an important role in maternal obesity-induced placental pathology. In conclusion, this is the first report on ER stress and UPR activation in the placenta of maternal obesity. Our findings represent the first step in the understanding of one of the key ER signaling pathways, also referred to IRE1α-XBP1, in placental pathophysiology affected by obesity, which may be an important mechanism accounting for the observed higher maternal and perinatal risks.

Published

2023

3. SARS-CoV-2 infection induces activation of ferroptosis in human placenta

Author

Bingbing Wang, Wei-Bin Shen, Peixin Yang, and Sifa Turan

Subjects

SARS-CoV-2, positive-sense strand, ferroptosis, ACSL4, placenta, adverse pregnancy outcomes, Biology (General), QH301-705.5

Abstract

Ferroptosis, a regulated non-apoptotic form of cell death, has been implicated in the response to varied types of infectious agents including virus. In this study, we sought to determine whether SARS-CoV-2 infection can induce activation of ferroptosis in the human placenta. We collected placentas from 23 pregnant females with laboratory-confirmed SARS-CoV-2 following delivery and then used RNA in situ hybridization assay for detection of viral positive-sense strand (PSS) to confirm that these placentas have been infected. We also used immunohistochemistry assay to assess expression levels of acyl-CoA synthetase long-chain family member 4 (ACSL4), an essential executioner of ferroptosis in the same specimens. Our results showed that ACSL4 expression was significantly increased in the group with positive positive-sense strand staining compared to their negative counterparts (p = 0.00022). Furthermore, we found that there was a positive trend for increased PSS staining along with increased ACSL4 expression. Our study supports that ferroptosis is activated in the response to SARS-CoV-2 infection in the human placenta, highlighting a molecular mechanism potentially linking this coronavirus infection and pathogenesis of adverse pregnancy outcomes.

Published

2022

4. Maternal obesity increases DNA methylation and decreases RNA methylation in the human placenta

Author

Wei-Bin, Shen, Jingxiang, Ni, Ruofan, Yao, Katherine R, Goetzinger, Christopher, Harman, E Albert, Reece, Bingbing, Wang, and Peixin, Yang

Subjects

Obesity, Maternal, Adenosine, Pregnancy, Placenta, 5-Methylcytosine, Humans, RNA, Female, Methyltransferases, DNA Methylation, Toxicology

Abstract

Maternal obesity is associated with increased risk of adverse pregnancy and birth outcomes. While increasing body of evidence supports that the etiology is related to fetal and placental hypoxia, molecular signaling changes in response to this pathophysiological condition in human placenta have remained elusive. Here by using varied approaches including immunocytochemistry staining, Western blot, RT-qPCR, and ELISA, we aimed to investigate the changes in epigenetic markers in placentas from obese pregnant women following delivery by Caesarean-section at term. Our results revealed that the levels of 5-methylcytosine (5mC), a methylated form commonly occurring in CpG dinucleotides and an important repressor of gene transcription in the genome, were significantly increased coupled with decreased activity of Ten-Eleven Translocation (TETs) enzymes that principally function by oxidizing 5mC in the obese placenta, consistent with hypoxia-induced genome-wide DNA hypermethylation observed in varied types of cells and tissues. N6-methyladenosine (m6A) represents the most abundant and conserved modification of gene transcripts, especially within mRNAs, which is stalled by m6A methyltransferases or "writers" including METTL-3/-14, WTAP, RBM15B, and KIAA1429. We further showed that obese placentas demonstrated significantly down-regulated levels of m6A along with reduced gene expression of WTAP, RBM15B, and KIAA1429. Our data support that maternal obesity-induced hypoxia may play an important role in triggering genome-wide DNA hypermethylation in the human placenta, and in turn leading to transcriptome-wide inhibition of RNA modifications. Our results further suggest that selectively modulating these pathways may facilitate development of novel therapeutic approaches for controlling and managing maternal obesity-associated adverse clinical outcomes.

Published

2022

5. Magnetic Enhancement of Stem Cell–Targeted Delivery into the Brain Following MR-Guided Focused Ultrasound for Opening the Blood–Brain Barrier

Author

Wei-Bin Shen, Pavlos Anastasiadis, Ben Nguyen, Deborah Yarnell, Paul J. Yarowsky, Victor Frenkel, and Paul S. Fishman

Subjects

Medicine

Abstract

Focused ultrasound (FUS)-mediated blood–brain barrier disruption (BBBD) can enable even large therapeutics such as stem cells to enter the brain from the bloodstream. However, the efficiency is relatively low. Our previous study showed that human neural progenitor cells (hNPCs) loaded with superparamagnetic iron oxide nanoparticles (SPIONs) in culture were attracted by an external magnetic field. In vivo, enhanced brain retention was observed near a magnet mounted on the skull in a rat model of traumatic brain injury, where BBBD also occurs. The goal of the current study was to determine whether magnetic attraction of SPION-loaded hNPCs would also enhance their retention in the brain after FUS-mediated BBBD. A small animal magnetic resonance imaging (MRI)-guided FUS system operating at 1.5 MHz was used to treat rats (∼120 g) without tissue damage or hemorrhage. Evidence of successful BBBD was validated with both radiologic enhancement of gadolinium on postsonication TI MRI and whole brain section visualization of Evans blue dye. The procedure was then combined with the application of a powerful magnet to the head directly after intravenous injection of the hNPCs. Validation of cells within the brain was performed by staining with Perls’ Prussian blue for iron and by immunohistochemistry with a human-specific antigen. By injecting equal numbers of iron oxide (SPIONs) and noniron oxide nanoparticles–loaded hNPCs, each labeled with a different fluorophore, we found significantly greater numbers of SPIONs-loaded cells retained in the brain at the site of BBBD as compared to noniron loaded cells. This result was most pronounced in regions of the brain closest to the skull (dorsal cortex) in proximity to the magnet surface. A more powerful magnet and a Halbach magnetic array resulted in more effective retention of SPION-labeled cells in even deeper brain regions such as the striatum and ventral cortex. There, up to 90% of hNPCs observed contained SPIONs compared to 60% to 70% with the less powerful magnet. Fewer cells were observed at 24 h posttreatment compared to 2 h (primarily in the dorsal cortex). These results demonstrate that magnetic attraction can substantially enhance the retention of stem cells after FUS-mediated BBBD. This procedure could provide a safer and less invasive approach for delivering stem cells to the brain, compared to direct intracranial injections, substantially reducing the risk of bleeding and infection.

Published

2017

6. A SARS-CoV-2 Delta Variant Case Manifesting as Extensive Placental Infection and Fetal Transmission

Author

Wei-Bin Shen, Shifa Turan, Bingbing Wang, Liviu Cojocaru, Christopher Harman, James Logue, E. Albert Reece, Matthew B. Frieman, and Peixin Yang

Subjects

Reproductive Medicine, Obstetrics and Gynecology, Case Report

Abstract

Introduction: Studies indicate a very low rate of SARS-CoV-2 detection in the placenta or occasionally a low rate of vertical transmission in COVID-19 pregnancy. SARS-CoV-2 Delta variant has become a dominant strain over the world and possesses higher infectivity due to mutations in its spike receptor-binding motif. Case Presentation: To determine whether SARS-CoV-2 Delta variant has increased potential for placenta infection and vertical transmission, we analyzed SARS-CoV-2 infection in the placenta, umbilical cord, and fetal membrane from a case where an unvaccinated mother and her neonate were COVID-19 positive. A 35-year-old primigravida with COVID-19 underwent an emergent cesarean delivery due to placental abruption in the setting of premature rupture of membranes. The neonate tested positive for SARS-CoV-2 within the first 24 h, and then again on days of life 2, 6, 13, and 21. The placenta exhibited intervillositis, increased fibrin deposition, and syncytiotrophoblast necrosis. Sequencing of viral RNA from fixed placental tissue revealed SAR-CoV-2 B.1.167.2 (Delta) variant. Both spike protein and viral RNA were abundantly present in syncytiotrophoblasts, cytotrophoblasts, umbilical cord vascular endothelium, and fetal membranes. Conclusion: We report with strong probability the first SARS-CoV-2 Delta variant transplacental transmission. Placental cells exhibited extensive apoptosis, senescence, and ferroptosis after SARS-CoV-2 Delta infection.

Published

2022

7. Cell-Based Therapy in TBI: Magnetic Retention of Neural Stem Cells in Vivo

Author

Wei-Bin Shen, Céline Plachez, Orest Tsymbalyuk, Natalya Tsymbalyuk, Su Xu, Aaron M. Smith, Sarah L. J. Michel, Deborah Yarnell, Roger Mullins, Rao P. Gullapalli, Adam Puche, J. Marc Simard, Paul S. Fishman, and Paul Yarowsky Ph.D.

Subjects

Medicine

Abstract

Stem cell therapy is under active investigation for traumatic brain injury (TBI). Noninvasive stem cell delivery is the preferred method, but retention of stem cells at the site of injury in TBI has proven challenging and impacts effectiveness. To investigate the effects of applying a magnetic field on cell homing and retention, we delivered human neuroprogenitor cells (hNPCs) labeled with a superparamagnetic nanoparticle into post-TBI animals in the presence of a static magnetic field. We have previously devised a method of loading hNPCs with ultrasmall superparamagnetic iron oxide (USPIO) nanoparticles Molday ION Rhodamine B (MIRB™). Labeling of hNPCs (MIRB-hNPCs) does not affect hNPC viability, proliferation, or differentiation. The 0.6 tesla (T) permanent magnet was placed ~4 mm above the injured parietal cortex prior to intracarotid injection of 4 × 10 4 MIRB-hNPCs. Fluorescence imaging, Perls' Prussian blue histochemistry, immunocytochemistry with SC121, a human-specific antibody, and T2-weighted magnetic resonance imaging ex vivo revealed there was increased homing and retention of MIRB-hNPCs in the injured cortex as compared to the control group in which MIRB-hNPCs were injected in the absence of a static magnetic field. Fluoro-Jade C staining and immunolabeling with specific markers confirmed the viability status of MIRB-hNPCs posttransplantation. These results show that increased homing and retention of MIRB-hNPCs post-TBI by applying a static magnetic field is a promising technique to deliver cells into the CNS for treatment of neurological injuries and neurodegenerative diseases.

Published

2016

8. SARS-CoV-2 invades cognitive centers of the brain and induces Alzheimer’s-like neuropathology

Author

Wei-Bin Shen, Montasir Elahi, James Logue, Penghua Yang, Lauren Baracco, E. Albert Reece, Bingbing Wang, Ling Li, Thomas G Blanchard, Zhe Han, Robert A Rissman, Matthew B Frieman, and Peixin Yang

Subjects

body regions, viruses, fungi, skin and connective tissue diseases, Article, respiratory tract diseases

Abstract

The neurotropism of SARS-CoV-2 and the phenotypes of infected neurons are still in debate. Long COVID manifests with “brain diseases” and the cause of these brain dysfunction is mysterious. Here, we analyze 34 age- and underlying disease-matched COVID-19 or non-COVID-19 human brains. SARS-CoV-2 RNA, nucleocapsid, and spike proteins are present in neurons of the cognitive centers of all COVID-19 patients, with its non-structural protein NSF2 detected in adult cases but not in the infant case, indicating viral replications in mature neurons. In adult COVID-19 patients without underlying neurodegeneration, SARS-CoV-2 infection triggers Aβ and p-tau deposition, degenerating neurons, microglia activation, and increased cytokine, in some cases with Aβ plaques and p-tau pretangles. The number of SARS-CoV-2+ cells is higher in patients with neurodegenerative diseases than in those without such conditions. SARS-CoV-2 further activates microglia and induces Aβ and p-tau deposits in non-Alzheimer’s neurodegenerative disease patients. SARS-CoV-2 infects mature neurons derived from inducible pluripotent stem cells from healthy and Alzheimer’s disease (AD) individuals through its receptor ACE2 and facilitator neuropilin-1. SARS-CoV-2 triggers AD-like gene programs in healthy neurons and exacerbates AD neuropathology. An AD infectious etiology gene signature is identified through SARS-CoV-2 infection and silencing the top three downregulated genes in human primary neurons recapitulates the neurodegenerative phenotypes of SARS-CoV-2. Thus, our data suggest that SARS-CoV-2 invades the brain and activates an AD-like program.

Published

2022

9. Maternal obesity-associated disruption of polarized lactate transporter MCT4 expression in human placenta

Author

Ruofan Yao, Penghua Yang, Katherine R. Goetzinger, Kristin L. Atkins, Wei-Bin Shen, Bingbing Wang, and Peixin Yang

Subjects

Monocarboxylic Acid Transporters, Obesity, Maternal, Pregnancy, Placenta, Humans, Muscle Proteins, Female, Lactic Acid, Obesity, Stillbirth, Toxicology

Abstract

Maternal obesity is associated with an increased risk of adverse pregnancy outcomes including stillbirth, and their etiology is thought to be related to placental and fetal hypoxia. In this study, we sought to investigate the levels of lactate in maternal and umbilical cord blood, a well characterized biomarker for hypoxia, and expression of plasma membrane lactate transporter MCT1 and MCT4 in the placental syncytiotrophoblast (STB), which are responsible for lactate uptake and extrusion, respectively, from pregnant women with a diagnosis of obesity following a Cesarean delivery at term. With use of approaches including immunofluorescence staining, Western blot, RT-qPCR and ELISA, our results revealed that in controls the expression of MCT1 was equally observed between basal (fetal-facing, BM) and microvillous (maternal-facing, MVM) membrane of the STB, whereas MCT4 was predominantly expressed in the MVM but barely detected in the BM. However, obese patients demonstrated significant decreased MCT4 abundance in the MVM coupled with concurrent elevated expression in the BM. We also found a linear trend toward decreasing MCT4 expression ratio of MVM to BM with increasing maternal pre-pregnancy BMI. Furthermore, our data showed that the lactate ratios of fetal cord arterial to maternal blood were remarkably reduced in obese samples compared to their normal counterparts. Collectively, these results suggest that the loss of polarization of lactate transporter MCT4 expression in placental STB leading to disruption of unidirectional lactate transport from the fetal to the maternal compartment may constitute part of mechanisms linking maternal obesity and pathogenesis of stillbirth.

Published

2022

10. Restoring BMP4 expression in vascular endothelial progenitors ameliorates maternal diabetes-induced apoptosis and neural tube defects

Author

Peixin Yang, Wei-Bin Shen, E. Albert Reece, and Songying Cao

Subjects

Male, 0301 basic medicine, Cancer Research, animal structures, Immunology, Apoptosis, Mice, Transgenic, Caspase 3, Bone Morphogenetic Protein 4, Biology, Article, Diabetes Mellitus, Experimental, Mice, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Vasculogenesis, Pregnancy, medicine, Animals, Neural Tube Defects, lcsh:QH573-671, Progenitor cell, Yolk sac, Endothelial Progenitor Cells, lcsh:Cytology, Embryogenesis, Cell Biology, Cell biology, Experimental models of disease, Neuroepithelial cell, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Neurulation, Bone morphogenetic protein 4, embryonic structures, Female, 030217 neurology & neurosurgery

Abstract

During mouse embryonic development, vasculogenesis initially occurs in the yolk sac, preceding neurulation. Our previous studies have demonstrated that maternal diabetes induces embryonic vasculopathy at early embryonic developmental stage by suppressing the expression of vascular growth factors including BMP4 (bone morphogenetic protein 4). This study aimed to determine whether restoring diabetes-inhibited BMP4 expression in Flk-1+ progenitors effectively prevented maternal diabetes-induced embryonic vasculopathy and NTDs. Transgenic (Tg) BMP4 expression in the vascular endothelial growth factor receptor 2 (Flk-1)-positive (Flk-1+) progenitors was achieved by crossing a Floxed BMP4 Tg mouse line with the Flk-1-Cre mouse line. Non-BMP4 Tg and BMP4 Tg embryos were harvested at E8.5 to assess the expression of BMP4, markers of endoplasmic reticulum stress, and expression of the Id genes, direct targets of BMP4; and the presence of cleaved caspase 3 and 8, apoptosis, and Smad signaling. BMP4 Tg overexpression neutralized its down-regulation by maternal diabetes in E8.5 embryos. Maternal diabetes-induced Flk-1+ progenitor apoptosis, impairment of blood island formation, and reduction of Flk-1+ progenitor number and blood vessel density, which were reversed by BMP4 Tg expression. BMP4 Tg expression in Flk-1+ progenitors blocked maternal diabetes-induced vasculopathy in early stage embryos (E7.5-E8.5) and consequently led to amelioration of maternal diabetes-induced neural tube defects (NTDs) at E10.5. BMP4 Tg expression inhibited maternal diabetes-induced endoplasmic reticulum stress and caspase cascade activation in the developing neuroepithelium, and reduced neuroepithelial cell apoptosis. BMP4 Tg expression re-activated Smad1/5/8 phosphorylation and reversed maternal diabetes-suppressed Smad4 expression. BMP4 Tg expression restored Id1 and Smad6 expression inhibited by maternal diabetes. In vitro, recombinant BMP4 protein blocked high glucose-induced Flk-1+ progenitor apoptosis and NTDs. These data demonstrate that BMP4 down-regulation in Flk-1+ progenitors are responsible for diabetes-induced yolk sac vasculopathy, and that restoring BMP4 expression prevents vasculopathy and rescues neuroepithelial cells from cellular organelle stress, leading to NTD reduction.

Published

2020

11. Functional cargos of exosomes derived from Flk-1

Author

Songying, Cao, Yanqing, Wu, E, Albert Reece, Cheng, Xu, Wei-Bin, Shen, Sunjay, Kaushal, and Peixin, Yang

Subjects

Diabetes, Gestational, Pregnancy, Survivin, Humans, Female, Fibroblast Growth Factor 2, Neural Tube Defects, Exosomes, Neurulation

Abstract

Various types of progenitors initiate individual organ formation and their crosstalk orchestrates morphogenesis for the entire embryo. Here we show that progenitor exosomal communication across embryonic organs occurs in normal development and is altered in embryos of diabetic pregnancy. Endoderm fibroblast growth factor 2 (FGF2) stimulates mesoderm Flk-1

Published

2020

12. Maternal diabetes induces senescence and neural tube defects sensitive to the senomorphic Rapamycin

Author

Hidetoshi Hasuwa, Cheng Xu, Wei-Bin Shen, Peixin Yang, E. Albert Reece, Sunjay Kaushal, and Christopher Harman

Subjects

Senescence, 0303 health sciences, congenital, hereditary, and neonatal diseases and abnormalities, Multidisciplinary, Cell cycle checkpoint, Transgene, Neural tube, SciAdv r-articles, Diseases and Disorders, Cell cycle, Biology, Cell biology, Neuroepithelial cell, 03 medical and health sciences, 0302 clinical medicine, Neurulation, medicine.anatomical_structure, Developmental Neuroscience, 030220 oncology & carcinogenesis, microRNA, medicine, Transcription factor, Research Articles, 030304 developmental biology, Research Article

Abstract

A microRNA-activated pathway in maternal diabetes–induced neuroepithelial cell senescence leads to neural tube defects., Neural tube defects (NTDs) are the second most common structural birth defect. Senescence, a state of permanent cell cycle arrest, occurs only after neural tube closure. Maternal diabetes–induced NTDs are severe diabetic complications that lead to infant mortality or lifelong morbidity and may be linked to premature senescence. Here, we report that premature senescence occurs in the mouse neuroepithelium and disrupts neurulation, leading to NTDs in diabetic pregnancy. Premature senescence and NTDs were abolished by knockout of the transcription factor Foxo3a, the miR-200c gene, and the cell cycle inhibitors p21 and p27; transgenic expression of the dominant-negative FoxO3a mutant; or the senomorphic rapamycin. Double transgenic expression of p21 and p27 mimicked maternal diabetes in inducing premature neuroepithelium senescence and NTDs. These findings integrate transcription- and epigenome-regulated miRNAs and cell cycle regulators in premature neuroepithelium senescence and provide a mechanistic basis for targeting premature senescence and NTDs using senomorphics.

Published

2020

13. Deficiency of the oxidative stress-responsive kinase p70S6K1 restores autophagy and ameliorates neural tube defects in diabetic embryopathy

Author

Wei-Bin Shen, E. Albert Reece, Peixin Yang, and Songying Cao

Subjects

Blood Glucose, Neuroepithelial Cells, Pregnancy in Diabetics, Apoptosis, In Vitro Techniques, Antioxidants, Article, Diabetes Mellitus, Experimental, Cyclic N-Oxides, 03 medical and health sciences, Mice, 0302 clinical medicine, Neural Stem Cells, Pregnancy, Autophagy, Medicine, Animals, 030212 general & internal medicine, Neural Tube Defects, Neurulation, PI3K/AKT/mTOR pathway, Mice, Knockout, Gene knockdown, 030219 obstetrics & reproductive medicine, business.industry, Endoplasmic reticulum, Autophagosomes, Obstetrics and Gynecology, Ribosomal Protein S6 Kinases, 70-kDa, Endoplasmic Reticulum Stress, Neural stem cell, Cell biology, Neuroepithelial cell, Fetal Diseases, Oxidative Stress, Diabetes Mellitus, Type 1, Glucose, Ribosomal protein s6, Unfolded protein response, Unfolded Protein Response, Female, Spin Labels, business, Microtubule-Associated Proteins

Abstract

BACKGROUND Autophagy is highly active in neuroepithelial cells of the developing neuroepithelium, and impaired autophagy leads to neural tube defects (NTDs). We have demonstrated that maternal diabetes induces NTDs, and that impaired autophagy and consequent cellular imbalance, including the endoplasmic reticulum (ER), where critical events occur leading to the induction of diabetic embryopathy. Because the mammalian target of rapamycin (mTOR) pathway suppresses autophagy, we hypothesize that p70S6K1 (70 kDa ribosomal protein S6 kinase 1), a major downstream effector of mTOR, mediates the inhibitory effect of maternal diabetes on autophagy in the developing neuroepithelium. OBJECTIVE We investigated whether p70S6K1 mediates the inhibitory effect of maternal diabetes on autophagy during neurulation. We also examined if p70S6K1 deficiency restores autophagy and thus relieves ER stress and inhibits maternal diabetes-induced apoptosis, which leads to reduction in NTD incidence in diabetic embryopathy. STUDY DESIGN Female p70S6K1 heterogeneous knockout (p70S6K1+/-) mice were bred with male p70S6K1 heterogeneous knockout (p70S6K1+/-) mice to generate wild type (WT), p70S6K1+/- and p70S6K1 knockout (p70S6K1-/-) embryos. Embryos at embryonic day 8.5 (E8.5) were harvested for the assessment of indices of autophagy, ER stress and apoptosis. NTDs incidence was determined in E10.5 embryos. For in vitro studies, siRNA knockdown of p70S6K1 in C17.2 mouse neural stem cells were used to determine the effect of p70S6K1 deficiency on autophagy impairment and ER stress under high glucose conditions. RESULTS Knockout of the Rps6kb1 gene, which encodes for p70S6K1, ameliorated maternal diabetes-induced NTDs and restored autophagosome formation in neuroepithelial cells suppressed by maternal diabetes. Maternal diabetes-suppressed conversion of LC3-I (Microtubule-associated protein 1A/1B-light chain 3) to LC3-II, an index of autophagic activity, in neurulation stage embryos was abrogated in the absence of p70S6K1. p70S6K1 knockdown in neural stem cells also restored autophagosome formation and the conversion of LC3-I to LC3-II. The activation of the major unfolded protein response (UPR), indicated by phosphorylation of IRE1α, PERK and eIF2α, and the increase of the endoplasmic reticulum (ER) stress marker, CHOP, were induced by maternal diabetes in vivo and high glucose in vitro. UPR and ER stress induced by maternal diabetes or high glucose were diminished by Rps6kb1deletionor p70S6K1 knockdown, respectively. Rps6kb1knockoutblocked maternal diabetes-induced caspase cleavage and neuroepithelial cell apoptosis. The SOD memetic Tempol abolished high glucose-induced p70S6K1 activation. CONCLUSION We revealed the critical involvement of p70S6K1 in the pathogenesis of diabetic embryopathy.

Published

2020

14. Maternal diabetes and high glucose in vitro trigger Sca1 + cardiac progenitor cell apoptosis through FoxO3a

Author

Penghua Yang, Xi Chen, Wendy W. Yang, Sunjay Kaushal, Daoyin Dong, and Wei-Bin Shen

Subjects

0301 basic medicine, medicine.medical_specialty, biology, Mutant, Biophysics, Cell Biology, Biochemistry, Embryonic stem cell, In vitro, Dephosphorylation, 03 medical and health sciences, Transactivation, 030104 developmental biology, Endocrinology, Apoptosis, Internal medicine, medicine, biology.protein, Molecular Biology, Transcription factor, Caspase

Abstract

Recent controversies surrounding the authenticity of c-kit+ cardiac progenitor cells significantly push back the advance in regenerative therapies for cardiovascular diseases. There is an urgent need for research in characterizing alternative types of cardiac progenitor cells. Towards this goal, in the present study, we determined the effect of maternal diabetes on Sca1+ cardiac progenitor cells. Maternal diabetes induced caspase 3-dependent apoptosis in Sca1+ cardiac progenitor cells derived from embryonic day 17.5 (E17.5). Similarly, high glucose in vitro but not the glucose osmotic control mannitol triggered Sca1+ cardiac progenitor cell apoptosis in a dose- and time-dependent manner. Both maternal diabetes and high glucose in vitro activated the pro-apoptotic transcription factor, Forkhead O 3a (FoxO3a) via dephosphorylation at threonine 32 (Thr-32) residue. foxo3a gene deletion abolished maternal diabetes-induced Sca1+ cardiac progenitor cell apoptosis. The dominant negative FoxO3a mutant without the transactivation domain from the C terminus blocked high glucose-induced Sca1+ cardiac progenitor cell apoptosis, whereas the constitutively active FoxO3a mutant with the three phosphorylation sites, Thr-32, Ser-253, and Ser-315, being replaced by alanine residues mimicked the pro-apoptotic effect of high glucose. Thus, maternal diabetes and high glucose in vitro may limit the regenerative potential of Sca1+ cardiac progenitor cells by inducing apoptosis through FoxO3a activation. These findings will serve as the guide in optimizing the autologous therapy using Sca1+ cardiac progenitor cells in cardiac defect babies born exposed to maternal diabetes.

Published

2017

15. 679: The newly determined role of miR17 and its target, Txnip, in the diabetes-induced Congenital Malformations

Author

Wei-Bin Shen, Peixin Yang, Penghua Yang, and E. Albert Reece

Subjects

business.industry, Diabetes mellitus, medicine, Obstetrics and Gynecology, Congenital malformations, Bioinformatics, medicine.disease, business, TXNIP

Published

2020

16. SIRB, sans iron oxide rhodamine B, a novel cross-linked dextran nanoparticle, labels human neuroprogenitor and SH-SY5Y neuroblastoma cells and serves as a USPIO cell labeling control

Author

Wei-Bin Shen, Ernest Groman, Dennis E. Vaccaro, Paul Yarowsky, and Paul S. Fishman

Subjects

0301 basic medicine, Iron oxide, Nanoparticle, Nanotechnology, 02 engineering and technology, Transfection, 021001 nanoscience & nanotechnology, 03 medical and health sciences, chemistry.chemical_compound, Surface coating, 030104 developmental biology, Dextran, chemistry, Cytoplasm, Biophysics, Rhodamine B, Radiology, Nuclear Medicine and imaging, 0210 nano-technology, Cytotoxicity

Abstract

This is the first report of the synthesis of a new nanoparticle, sans iron oxide rhodamine B (SIRB), an example of a new class of nanoparticles. SIRB is designed to provide all of the cell labeling properties of the ultrasmall superparamagnetic iron oxide (USPIO) nanoparticle Molday ION Rhodamine B (MIRB) without containing the iron oxide core. MIRB was developed to label cells and allow them to be tracked by MRI or to be manipulated by magnetic gradients. SIRB possesses a similar size, charge and cross-linked dextran coating as MIRB. Of great interest is understanding the biological and physiological changes in cells after they are labeled with a USPIO. Whether these effects are due to the iron oxide buried within the nanoparticle or to the surface coating surrounding the iron oxide core has not been considered previously. MIRB and SIRB represent an ideal pairing of nanoparticles to identify nanoparticle anatomy responsible for post-labeling cytotoxicity. Here we report the effects of SIRB labeling on the SH-SY5Y neuroblastoma cell line and primary human neuroprogenitor cells (hNPCs). These effects are contrasted with the effects of labeling SH-SY5Y cells and hNPCs with MIRB. We find that SIRB labeling, like MIRB labeling, (i) occurs without the use of transfection reagents, (ii) is packaged within lysosomes distributed within cell cytoplasm, (iii) is retained within cells with no loss of label after cell storage, and (iv) does not alter cellular viability or proliferation, and (v) SIRB labeled hNPCs differentiate normally into neurons or astrocytes. Copyright © 2016 John Wiley & Sons, Ltd.

Published

2016

17. Maternal diabetes induces senescence and neural tube defects sensitive to the senomorphic rapamycin.

Author

Cheng Xu, Wei-Bin Shen, Reece, E. Albert, Hidetoshi Hasuwa, Harman, Christopher, Kaushal, Sunjay, and Peixin Yang

Subjects

*NEURAL tube defects, *AGING, *RAPAMYCIN, *NEURAL tube, *GENE expression

Abstract

Neural tube defects (NTDs) are the second most common structural birth defect. Senescence, a state of permanent cell cycle arrest, occurs only after neural tube closure. Maternal diabetes-induced NTDs are severe diabetic complications that lead to infant mortality or lifelong morbidity and may be linked to premature senescence. Here, we report that premature senescence occurs in the mouse neuroepithelium and disrupts neurulation, leading to NTDs in diabetic pregnancy. Premature senescence and NTDs were abolished by knockout of the transcription factor Foxo3a, the miR-200c gene, and the cell cycle inhibitors p21 and p27; transgenic expression of the dominant-negative FoxO3a mutant; or the senomorphic rapamycin. Double transgenic expression of p21 and p27 mimicked maternal diabetes in inducing premature neuroepithelium senescence and NTDs. These findings integrate transcription- and epigenome-regulated miRNAs and cell cycle regulators in premature neuroepithelium senescence and provide a mechanistic basis for targeting premature senescence and NTDs using senomorphics. [ABSTRACT FROM AUTHOR]

Published

2021

18. 92: A novel epigenetic mechanism underlying maternal diabetes-suppressed mitochondrial fusion in congenital heart disease

Author

Wei-Bin Shen, Wenhui Lu, E. Albert Reece, and Peixin Yang

Subjects

mitochondrial fusion, Heart disease, business.industry, medicine, Obstetrics and Gynecology, Maternal diabetes, Bioinformatics, medicine.disease, business, Epigenetic Mechanism

Published

2020

19. 1033: Obesity-induced epigenetic changes associated with adverse perinatal outcomes

Author

Wei-Bin Shen, Ruofan Yao, Jingxiang Ni, E. Albert Reece, Christopher Harman, Peixin Yang, and Penghua Yang

Subjects

business.industry, Obstetrics and Gynecology, Medicine, Epigenetics, business, Bioinformatics, medicine.disease, Obesity

Published

2020

20. 489: Restoring BMP4 expression in vascular endothelial progenitors ameliorates maternal diabetes-induced vasculopathy and neural tube defects

Author

Wei-Bin Shen, Songying Cao, Peixin Yang, and E. Albert Reece

Subjects

medicine.anatomical_structure, business.industry, Neural tube, medicine, Cancer research, Obstetrics and Gynecology, Maternal diabetes, Progenitor cell, business

Published

2020

21. Maternal Diabetes Induces Congenital Heart Defects by Suppressing Mitochondrial Fusion through the miR-140 Mitofusin 1 Circuit

Author

Wei-Bin Shen, Peixin Yang, and Xi Chen

Subjects

mitochondrial fusion, Kinase, Apoptosis, Endocrinology, Diabetes and Metabolism, Gene expression, Internal Medicine, MFN1, Promoter, Biology, Gene, Transcription factor, Cell biology

Abstract

Pregestational maternal diabetes is a significant risk factor for congenital heart defects (CHDs) in the offspring. Increased apoptosis is implicated in CHD formation, yet the underlying mechanism is still unclear. Mitochondrial fusion and fission dynamics play a key role in the regulation of cell viability. Embryonic cardiomyocytes exposed to maternal diabetes display impaired fusion and enhanced fission, suggesting that maternal diabetes represses mitofusion gene expression. Here, we demonstrated that maternal diabetes in vivo and high glucose in vitro significantly increased microRNA-140 (miR140) expression whereas down-regulated its putative target gene Mitofusin 1 (Mfn1) expression in cardiomyocytes. We found that miR140 bound to the 3’ untranslated region of Mfn1 mRNA, leading to Mfn1 mRNA degradation. A miR140 mimic induced mitochondrial fragmentation, Mfn1 reduction and cell apoptosis, whereas a miR-140 inhibitor abrogated high glucose-repressed Mfn1 expression and mitochondrial fusion. Deletion of the miR140 gene in vivo reversed diabetes-suppressed Mfn1 expression, restored mitochondrial fusion, blocked cardiac cell apoptosis leading to a significant reduction of CHDs in diabetic pregnancy. Analysis of the miR-140 gene promoter revealed several putative binding sites of the transcription factor, c-Jun, which is downstream of JNK2. Deletion of the Jnk2 (c-Jun NH2-terminal kinase 2) gene using the JNK2-/- mice mimicked the effect of miR-140 deficiency in suppressing diabetes-induced CHDs. JNK2 deletion abolished the increase of miR-140 and restored Mnf1 expression and mitochondrial fusion. Our findings support the hypothesis that the JNK2-miR140-Mfn1 circuit is critically involved in maternal diabetes-induced mitochondrial fusion impairment and CHD formation. Disclosure X. Chen: None. W. Shen: None. P. Yang: None.

Published

2018

22. High Glucose Inhibits Neural Stem Cell Differentiation Through Oxidative Stress and Endoplasmic Reticulum Stress

Author

Wei-Bin Shen, Penghua Yang, Peixin Yang, Xi Chen, Winny Sun, and Daoyin Dong

Subjects

0301 basic medicine, Apoptosis, Biology, medicine.disease_cause, Antioxidants, Cyclic N-Oxides, 03 medical and health sciences, Mice, 0302 clinical medicine, Original Research Reports, Neural Stem Cells, Tubulin, Glial Fibrillary Acidic Protein, medicine, Animals, Neurons, Dose-Response Relationship, Drug, Endoplasmic reticulum, Neurogenesis, Neural tube, Cell Differentiation, Cell Biology, Hematology, Endoplasmic Reticulum Stress, Embryonic stem cell, Neural stem cell, Cell biology, Neuroepithelial cell, Oxidative Stress, 030104 developmental biology, medicine.anatomical_structure, Glucose, Spin Labels, Neuron, 030217 neurology & neurosurgery, Oxidative stress, Biomarkers, Developmental Biology

Abstract

Maternal diabetes induces neural tube defects by suppressing neurogenesis in the developing neuroepithelium. Our recent study further revealed that high glucose inhibited embryonic stem cell differentiation into neural lineage cells. However, the mechanism whereby high glucose suppresses neural differentiation is unclear. To investigate whether high glucose-induced oxidative stress and endoplasmic reticulum (ER) stress lead to the inhibition of neural differentiation, the effect of high glucose on neural stem cell (the C17.2 cell line) differentiation was examined. Neural stem cells were cultured in normal glucose (5 mM) or high glucose (25 mM) differentiation medium for 3, 5, and 7 days. High glucose suppressed neural stem cell differentiation by significantly decreasing the expression of the neuron marker Tuj1 and the glial cell marker GFAP and the numbers of Tuj1(+) and GFAP(+) cells. The antioxidant enzyme superoxide dismutase mimetic Tempol reversed high glucose-decreased Tuj1 and GFAP expression and restored the numbers of neurons and glial cells differentiated from neural stem cells. Hydrogen peroxide treatment imitated the inhibitory effect of high glucose on neural stem cell differentiation. Both high glucose and hydrogen peroxide triggered ER stress, whereas Tempol blocked high glucose-induced ER stress. The ER stress inhibitor, 4-phenylbutyrate, abolished the inhibition of high glucose or hydrogen peroxide on neural stem cell differentiation. Thus, oxidative stress and its resultant ER stress mediate the inhibitory effect of high glucose on neural stem cell differentiation.

Published

2018

23. The current status and future of cardiac stem/progenitor cell therapy for congenital heart defects from diabetic pregnancy

Author

Wei-Bin Shen, Jianxiang Zhong, Shengbing Wang, Peixin Yang, and Sunjay Kaushal

Subjects

0301 basic medicine, Cardiac function curve, Heart Defects, Congenital, medicine.medical_specialty, Cellular differentiation, 030204 cardiovascular system & hematology, Bioinformatics, Article, 03 medical and health sciences, Paracrine signalling, Mice, 0302 clinical medicine, Pregnancy, Internal medicine, medicine, Myocyte, Animals, Humans, Cell Lineage, Myocytes, Cardiac, Progenitor cell, Cells, Cultured, Embryonic Stem Cells, business.industry, Multipotent Stem Cells, Mesenchymal stem cell, Cell Differentiation, Embryonic stem cell, Diabetes, Gestational, Proto-Oncogene Proteins c-kit, 030104 developmental biology, Immune System, Pediatrics, Perinatology and Child Health, Cardiology, Heart Transplantation, Pregnancy, Animal, Female, Stem cell, business, Stem Cell Transplantation

Abstract

Pregestational maternal diabetes induces congenital heart defects (CHDs). Cardiac dysfunction after palliative surgical procedures contributes to the high mortality of CHD patients. Autologous or allogeneic stem cell therapies are effective for improving cardiac function in animal models and clinical trials. c-kit+ cardiac progenitor cells (CPCs), the most recognized CPCs, have the following basic properties of stem cells: self-renewal, multicellular clone formation, and differentiation into multiple cardiac lineages. However, there is ongoing debate regarding whether c-kit+ CPCs can give rise to sufficient cardiomyocytes. A new hypothesis to address the beneficial effect of c-kit+ CPCs is that these cells stimulate endogenous cardiac cells through a paracrine function in producing a robust secretome and exosomes. The values of other cardiac CPCs, including Sca1+ CPCs and cardiosphere-derived cells, are beginning to be revealed. These cells may be better choices than c-kit+ CPCs for generating cardiomyocytes. Adult mesenchymal stem cells are considered immune-incompetent and effective for improving cardiac function. Autologous CPC therapy may be limited by the observation that maternal diabetes adversely affects the biological function of embryonic stem cells and CPCs. Future studies should focus on determining the mechanistic action of these cells, identifying new CPC markers, selecting highly effective CPCs, and engineering cell-free products.

Published

2017

24. Research on Composite Flocculant Improving Substrate Sludge Dehydration

Author

Wei Bin Shen, Qi Lun Zhang, Chun Ming Wang, Cui Ming Li, and Yun Hua Gao

Subjects

Flocculation, Materials science, Volume (thermodynamics), Composite number, General Engineering, Environmental engineering, medicine, Substrate (chemistry), Dehydration, medicine.disease, Pulp and paper industry, Water content, Dewatering

Abstract

The dewatering effects of FeCl3, AlCl3 and PAM as flocculants for substrate sludge in Poyang Lake of SCAU were tested. The indexes, such as the filtrating volume, the moisture content, etc, were compared in order to achieve the best composite flocculant. The results showed that, when FeCl3 was used with PAM in the ratio of 4:1, the highest filtrate volume 75mL was obtained. At the same time, when the dosing quantity is 3%, we obtained the best dewatering performances, such as the fastest velocity of filtrate, the highest degree of clarity with 88%, which were better than other flocculants.

Published

2013

25. 5th International Symposium on Focused Ultrasound

Author

Abounader, Roger, Abraham, Christopher, Adema, Gosse, Agrawal, Punit, Airan, Raag, Aleman, Dionne, Alexander, Phillip, Alkins, Ryan, Alnazeer, Moez, Altman, Michael, Aly, Amirah, Amaral, Joao G., Amrahli, Maral, Amraoui, Sana, Andarawewa, Kumari, Andriyakhina, Yulia, Angstadt, Mary, Ankou, Bénédicte, Arias, Ana C., Arvanitis, Costas, Asadnia, Kiana, Aubert, Isabelle, Aubry, Jean-Francois, Aurup, Christian, Bader, Kenneth, Badr, Lena, Baek, Hongchae, Barbato, Gaetano, Beccaria, Kevin, Bellorofonte, Carlo, Benson, Lee, Bernus, Olivier, Berriet, Rémi, Bertolina, Jim, Beskin, Viktoriya, Bessière, Francis, Bethune, Allison, Bezzi, Mario, Bond, Aaron, Bonomo, Guido, Borowsky, Alexander, Borys, Nicolas, Böttcher, Joachim, Bouley, Donna, Bour, Pierre, Bourekas, Eric, Brenin, David, Brokman, Omer, Brosh, Inbar, Buckner, Andrew, Bullock, Timothy, Cafarelli, Andrea, Cahill, Jessica, Camarena, Francisco, Camelo-Piragua, Sandra, Campbell, Benjamin, Campbell, Fiona, Cannata, Jon, Canney, Michael, Carlson, Roy, Carneiro, Antonio, Carpentier, Alexandre, Catheline, Stefan, Cavin, Ian, Cesana, Claudio, Chabok, Hamid R., Chamanara, Marzieh, Chang, Jin H., Chang, Won S., Changizi, Barbara, Chapelon, Jean Y., Chaplin, Vandiver, Chapman, Martin, Chaudhary, Neeraj, Chaussy, Christian, Chen, Cherry, Chen, Johnny, Chen, Wohsing, Chen, Xiaoming, Chevalier, Philippe, Chiou, George, Chisholm, Alexander, Christofferson, Ivy, Chung, Hyun H., Ciuti, Gastone, Clement, Gregory, Cooper, Mark, Corea, Joseph, Corso, Cristiano, Cosman, Josh, Coughlin, Dezba, Crake, Calum, Cunitz, Bryan, Curiel, Laura, Curley, Colleen T., Czarnota, Gregory, Dababou, Susan, Dallapiazza, Robert, de Bever, Joshua, de Jager, Bram, de Ruiter, Joost, de Senneville, Baudouin D., Deckers, Roel, Delattre, Jean-Yves, den Brok, Martijn, Dhanaliwala, Ali, Diodato, Alessandro, Dixon, Adam, Donner, Elizabeth, Downs, Matthew, Du, Zhongmin, Dubois, Rémi, Dupre, Aurelien, Eikelenboom, Dylan, Elias, W. J., Ellens, Nicholas, Endre, Ruby, Eran, Ayelet, Erasmus, Hans-Peter, Everstine, Ashli, Farahani, Keyvan, Farrer, Alexis, Farry, Justin, Federau, Christian, Feng, Xue, Ferrer, Cyril, Ferrera, Vincent, Fishman, Paul, Foley, Jessica, Frenkel, Victor, Fütterer, Jurgen, Gach, H. M., Gandhi, Dheeraj, Gertner, Michael, Goldsher, Dorit, Gorgone, Alessandro, Greillier, Paul, Griesenauer, Rebekah, Grissom, William, Grondin, Julien, Guha, Chandan, Gulati, Amitabh, Gullapalli, Rao, Guo, Sijia, Gupta, Samit, Gurm, Hitinder, Gwinn, Ryder, Hadley, Rock, Haïssaguerre, Michel, Hammoud, Dima, Hananel, Arik, Hargrove, Amelia, Hatch, Robert, Haworth, Kevin, Hazan, Eilon, He, Ye, Heemels, Maurice, Heerschap, Arend, Hilas, Elaine, Hoang-Xuan, Khe, Hocini, Mélèze, Hodaie, Mojgan, Hofmann, Denis, Holland, Christy, Hoogenboom, Martijn, Hopyan, Sevan, Hossack, John, Houdouin, Alexandre, Hsu, Po-Hung, Hu, Jim, Hurwitz, Mark, Huss, Diane, Hwang, Chang-il, Hwang, Joo H., Idbaih, Ahmed, Ikeuchi, Masahiko, Ingham, Elizabeth, Ives, Kimberly, Izumi, Masashi, Jackson-Lewis, Vernice, Janát-Amsbury, Margit, Jang, Kee W., Jedruszczuk, Kathleen, Jiménez-Gambín, Sergio, Jiménez, Noé, Johnson, Sara, Jonathan, Sumeeth, Joy, Joyce, Jung, Hyun H., Jung, Na Y., Kahn, Itamar, Kamimura, Hermes, Kamrava, Seyed K., Kang, Jeeun, Kang, Kook J., Kang, Soo Y., Kao, Yi-tzu, Katti, Prateek, Kawasaki, Motohiro, Kaye, Elena, Keupp, Jochen, Kim, AeRang, Kim, Harry, Kim, Hyun-Chul, Kim, Hyuncheol, Kim, Hyungmin, Kim, Min S., Kim, Namho, Kiyasu, Katsuhito, Kneepkens, Esther, Knopp, Michael, Kobus, Thiele, Koral, Korgun, Kreider, Wayne, Krishna, Vibhor, Krug, Roland, Krupa, Steve, Kuo, Chia-Chun, Kwiecinski, Wojciech, Lacoste, Romain, Lam, Heather, Lamberti-Pasculli, Maria, Lang, Brian, Larner, James, Larrabee, Zachary, Leach, J. K., LeBlang, Suzanne, Leclercq, Delphine, Lee, Hak J., Lee, Jong-Hwan, Lehericy, Stéphane, Leighton, Wan, Leung, Steven, Lewis, Bobbi, Lewis, Matthew, Li, Dawei, Linn, Sabine, Lipsman, Nir, Liu, Hao-Li, Liu, Jingfei, Lopes, M. B., Lotz, Jeff, Lu, Xin, Lundt, Jonathan, Luo, Xi, Lustgarten, Lior, Lustig, Micheal, Macoskey, Jonathan, Madore, Bruno, Maev, Roman, Magat, Julie, Maimbourg, Guillaume, Maimon, Noam, Mainprize, Todd, Malayer, Jerry, Maples, Danny, Marquet, Fabrice, Marrocchio, Cristina, Marx, Mike, Mastorakos, Panagiotis, Mauri, Giovanni, McLean, Hailey, McMichael, John, Mead, Brian P., Melodelima, David, Melot-Dusseau, Sandrine, Menciassi, Arianna, Merrill, Robb, Meyer, Joshua, Midiri, Massimo, Miga, Michael, Migliore, Ilaria G., Miller, Eric, Minalga, Emilee, Moon, Hyungwon, Moore, David, Mourad, Pierre, Mouratidis, Petros, Mueller, Michael, Mugler, John, Muller, Sébastien, Namba, Hirofumi, Naor, Omer, Nassar, Maria, Nazai, Navid, Negron, Karina, Negussie, Ayele, Nguyen, Thai-Son, Nicolay, Klaas, Nikolaeva, Anastasia V., Oetgen, Matthew, Olive, Kenneth, Olumolade, Oluyemi, Orsi, Franco, Owens, Gabe, Ozilgen, Arda, Padegimas, Linas, Palermo, Carmine, Pan, Chia-Hsin, Pandey, Aditya, Papadakis, Georgios, Park, Chang K., Park, Sang M., Parker, Jonathon, Parvizi, Mohammad H., Pascal-Tenorio, Aurea, Patel, Janish, Patz, Sam, Payen, Thomas, Perich, Eloi, Pernot, Mathieu, Perol, David, Perry, James, Pillarisetty, Venu, Pioche, Mathieu, Pizzuto, Matthew, Plaksin, Michael, Plata, Juan, Price, Karl, Prince, Jessica, Przedborski, Serge, Quinones-Hinojosa, Alfredo, Ramachandran, Akhilesh, Ranjan, Ashish, Ravikumar, Vinod, Reichenbach, Juergen, Repasky, Elizabeth, Rezai, Ali, Ritter, Philippe, Rivoire, Michel, Rochman, Carrie, Rosenberg, Jarrett, Rosnitskiy, Pavel B., Ruiz, Antonio, Sahgal, Arjun, Samiotaki, Gesthimani, Sanghvi, Narendra, Santin, Mathieu D., Santos, Domiciano, Sasaki, Noboru, Sastra, Steve, Schade, George, Schall, Jeffrey, Schlesinger, Ilana, Schmitt, Paul, Schwaab, Julia, Scionti, Stephen, Scipione, Roberto, Scoarughi, Gian L., Scott, Serena, Sebeke, Lukas, Seifabadi, Reza, Seo, Jai, Sesenoglu-Laird, Ozge, Shah, Binit, Shahriari, Kian, Shaikh, Sumbul, Shea, Jill, Shi, Jiaqi, Shim, Jenny, Shinkov, Alexander, Shuman, Jillian, Silvestrini, Matthew, Sim, Changbeom, Sin, Vivian, Sinai, Alon, Singh, Manoj, Sinilshchikov, Ilya, Skalina, Karin, Slingluff, Craig, So, Po-Wah, Solomon, Stephen, Son, Keon H., Sperling, Scott, Stein, Ruben, Stein, Sherman, Stevens, Aaron, Stimec, Jennifer, Storm, Gert, Straube, William, Suelmann, Britt, Sutton, Jonathan, Svedin, Bryant, Takemasa, Ryuichi, Takiguchi, Mitsuyoshi, Tam, Emily, Tan, Jeremy, Tang, Xinyan, Tanter, Mickael, Tebebi, Pamela, Tehrani, Seruz, Temple, Michael, Teofilovic, Dejan, ter Haar, Gail, Terzi, Marina E., Thueroff, Stefan, Timbie, Kelsie, Tognarelli, Selene, Tretbar, Steffen, Trudeau, Maureen, Tsai, Yi-Chieh, Tsysar, Sergey A., Tucci, Samantha, Tuveson, David, Ushida, Takahiro, Vaessen, Paul, Vaillant, Fanny, Van Arsdell, Glen, van Breugel, Johanna, Van der Jeugd, Anneke, Van der Wall, Elsken, van Diest, Paul, van Stralen, Marijn, Varano, Gianluca, Velat, Manuela, Vidal-Jove, Joan, Vigna, Paolo D., Vignot, Alexandre, Vincenot, Jeremy, Vykhodtseva, Natalia, Wang, Bin, Wang, Han, Wang, Kevin, Wang, Qi, Wang, Qingguo, Wang, Shengping, Wang, Yak-Nam, Wang, Zhaorui, Wardlow, Rachel, Warren, Amy, Waszczak, Barbara, Watson, Katherine, Webb, Taylor, Wei-Bin, Shen, Wei, Kuo-Chen, Weiss, Steffen, Weissler, Yoni, Werner, Beat, Wesseling, Pieter, Williams, Noelle, Wilson, Emmanuel, Wintermark, Max, Witkamp, Arjen, Wong, Carlos, Wu, Jing-Fu, Wydra, Adrian, Xu, Alexis, Xu, Doudou, Xu, Su, Yang, Georgiana, Yang, Nai-Yi, Yao, Chen, Yarowsky, Paul, Ye, Patrick P., Yuldashev, Petr, Zaaroor, Menashe, Zachiu, Cornel, Zahos, Peter, Zangos, Stephan, Zhang, Dandan, Zhang, Hua, Zhang, Jimin, Zhang, Junhai, Zhang, Xi, Zhao, Li, Zhong, Pei, Zhuo, Jiachen, Zidowitz, Stephan, Zinke, Wolf, Zorgani, Ali, and Aerospace and Ocean Engineering

Subjects

GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries)

Abstract

Published version

Published

2016

26. Maternal diabetes and high glucose in vitro trigger Sca1

Author

Penghua, Yang, Wendy W, Yang, Xi, Chen, Sunjay, Kaushal, Daoyin, Dong, and Wei-Bin, Shen

Subjects

Heart Defects, Congenital, Caspase 3, Myocardium, Stem Cells, Forkhead Box Protein O3, Apoptosis, Heart, Embryo, Mammalian, Mice, Inbred C57BL, Diabetes, Gestational, Glucose, Pregnancy, Animals, Female, Ataxin-1, Gene Deletion

Abstract

Recent controversies surrounding the authenticity of c-kit

Published

2016

27. Type 2 diabetes mellitus induces congenital heart defects in murine embryos by increasing oxidative stress, endoplasmic reticulum stress, and apoptosis

Author

Wei-Bin Shen, Yanqing Wu, Jianxiang Zhong, Daoyin Dong, E. Albert Reece, Peixin Yang, and Christopher Harman

Subjects

0301 basic medicine, X-Box Binding Protein 1, Apoptosis, Type 2 diabetes, medicine.disease_cause, Endoplasmic Reticulum, 0302 clinical medicine, Pregnancy, Phosphorylation, Endoplasmic Reticulum Chaperone BiP, Heat-Shock Proteins, Caspase 8, 030219 obstetrics & reproductive medicine, Embryonic heart, biology, Caspase 3, Obstetrics and Gynecology, Endoplasmic Reticulum Stress, Female, Binding immunoglobulin protein, Heart Defects, Congenital, medicine.medical_specialty, Normal diet, RNA Splicing, Protein Serine-Threonine Kinases, Article, Diabetes Mellitus, Experimental, 03 medical and health sciences, Internal medicine, Diabetes mellitus, Endoribonucleases, medicine, Animals, business.industry, Endoplasmic reticulum, Myocardium, Type 2 Diabetes Mellitus, medicine.disease, Embryo, Mammalian, Mice, Inbred C57BL, Diabetes, Gestational, Oxidative Stress, 030104 developmental biology, Endocrinology, biology.protein, Lipid Peroxidation, business, Protein Kinases, Oxidative stress, Transcription Factor CHOP

Abstract

Background Maternal type 1 and 2 diabetes mellitus are strongly associated with high rates of severe structural birth defects, including congenital heart defects. Studies in type 1 diabetic embryopathy animal models have demonstrated that cellular stress-induced apoptosis mediates the teratogenicity of maternal diabetes leading to congenital heart defect formation. However, the mechanisms underlying maternal type 2 diabetes mellitus–induced congenital heart defects remain largely unknown. Objective We aim to determine whether oxidative stress, endoplasmic reticulum stress, and excessive apoptosis are the intracellular molecular mechanisms underlying maternal type 2 diabetes mellitus–induced congenital heart defects. Study Design A mouse model of maternal type 2 diabetes mellitus was established by feeding female mice a high-fat diet (60% fat). After 15 weeks on the high-fat diet, the mice showed characteristics of maternal type 2 diabetes mellitus. Control dams were either fed a normal diet (10% fat) or the high-fat diet during pregnancy only. Female mice from the high-fat diet group and the 2 control groups were mated with male mice that were fed a normal diet. At E12.5, embryonic hearts were harvested to determine the levels of lipid peroxides and superoxide, endoplasmic reticulum stress markers, cleaved caspase 3 and 8, and apoptosis. E17.5 embryonic hearts were harvested for the detection of congenital heart defect formation using India ink vessel patterning and histological examination. Results Maternal type 2 diabetes mellitus significantly induced ventricular septal defects and persistent truncus arteriosus in the developing heart, along with increasing oxidative stress markers, including superoxide and lipid peroxidation; endoplasmic reticulum stress markers, including protein levels of phosphorylated-protein kinase RNA-like endoplasmic reticulum kinase, phosphorylated-IRE1α, phosphorylated-eIF2α, C/EBP homologous protein, and binding immunoglobulin protein; endoplasmic reticulum chaperone gene expression; and XBP1 messenger RNA splicing, as well as increased cleaved caspase 3 and 8 in embryonic hearts. Furthermore, maternal type 2 diabetes mellitus triggered excessive apoptosis in ventricular myocardium, endocardial cushion, and outflow tract of the embryonic heart. Conclusion Similar to those observations in type 1 diabetic embryopathy, maternal type 2 diabetes mellitus causes heart defects in the developing embryo manifested with oxidative stress, endoplasmic reticulum stress, and excessive apoptosis in heart cells.

Published

2016

28. High glucose suppresses embryonic stem cell differentiation into neural lineage cells

Author

Penghua Yang, E. Albert Reece, Xi Chen, Wei-Bin Shen, and Peixin Yang

Subjects

0301 basic medicine, medicine.medical_specialty, Cellular differentiation, Neurogenesis, Biophysics, Biology, Biochemistry, Article, Cell Line, 03 medical and health sciences, Mice, 0302 clinical medicine, Neural Stem Cells, Neurosphere, Internal medicine, medicine, Animals, Molecular Biology, Embryonic Stem Cells, Neurons, Dose-Response Relationship, Drug, Neural tube, Neural crest, Cell Differentiation, Cell Biology, Neural stem cell, Neuroepithelial cell, 030104 developmental biology, medicine.anatomical_structure, Endocrinology, Glucose, embryonic structures, 030217 neurology & neurosurgery, Adult stem cell

Abstract

Abnormal neurogenesis occurs during embryonic development in human diabetic pregnancies and in animal models of diabetic embryopathy. Our previous studies in a mouse model of diabetic embryopathy have implicated that high glucose of maternal diabetes delays neurogenesis in the developing neuroepithelium leading to neural tube defects. However, the underlying process in high glucose-impaired neurogenesis is uncharacterized. Neurogenesis from embryonic stem (ES) cells provides a valuable model for understanding the abnormal neural lineage development under high glucose conditions. ES cells are commonly generated and maintained in high glucose (approximately 25 mM glucose). Here, the mouse ES cell line, E14, was gradually adapted to and maintained in low glucose (5 mM), and became a glucose responsive E14 (GR-E14) line. High glucose induced the endoplasmic reticulum stress marker, CHOP, in GR-E14 cells. Under low glucose conditions, the GR-E14 cells retained their pluripotency and capability to differentiate into neural lineage cells. GR-E14 cell differentiation into neural stem cells (Sox1 and nestin positive cells) was inhibited by high glucose. Neuron (Tuj1 positive cells) and glia (GFAP positive cells) differentiation from GR-E14 cells was also suppressed by high glucose. In addition, high glucose delayed GR-E14 differentiation into neural crest cells by decreasing neural crest markers, paired box 3 (Pax3) and paired box 7 (Pax7). Thus, high glucose impairs ES cell differentiation into neural lineage cells. The low glucose adapted and high glucose responsive GR-E14 cell line is a useful in vitro model for assessing the adverse effect of high glucose on the development of the central nervous system.

Published

2016

29. Environmental neurotoxin-induced progressive model of parkinsonism in rats

Author

Sarah M. Clark, Kimberly M. Valentino, Aubrey A. Siebert, Wei-Bin Shen, Carole Sztalryd, Christopher A. Shaw, Hyder A. Jinnah, Paul Yarowsky, Natalie V. Dugger, M. Samir Jafri, Paul S. Fishman, and Kimberly A. McDowell

Subjects

Cycas, Male, Pathology, medicine.medical_specialty, Flour, Neurotoxins, Population, Physiology, In Vitro Techniques, Biology, Rats, Sprague-Dawley, Parkinsonian Disorders, medicine, Animals, Neurotoxin, Amyotrophic lateral sclerosis, education, Parkinsonism dementia, Neurons, education.field_of_study, Dyskinesias, Plant Extracts, Parkinsonism, fungi, Brain, food and beverages, biology.organism_classification, medicine.disease, Diet, Rats, Cycas micronesica, Disease Models, Animal, Spinal Cord, Neurology, Nerve Degeneration, Disease Progression, Causal link, Neurology (clinical)

Abstract

Exposure to a number of drugs, chemicals, or environmental factors can cause parkinsonism. Epidemiologic evidence supports a causal link between the consumption of flour made from the washed seeds of the plant Cycas micronesica by the Chamorro population of Guam and the development of amyotrophic lateral sclerosis/parkinsonism dementia complex.We now report that consumption of washed cycad flour pellets by Sprague-Dawley male rats induces progressive parkinsonism.Cycad-fed rats displayed motor abnormalities after 2 to 3 months of feeding such as spontaneous unilateral rotation, shuffling gait, and stereotypy. Histological and biochemical examination of brains from cycad-fed rats revealed an initial decrease in the levels of dopamine and its metabolites in the striatum (STR), followed by neurodegeneration of dopaminergic (DAergic) cell bodies in the substantia nigra (SN) pars compacta (SNc). alpha-Synuclein (alpha-syn; proteinase K-resistant) and ubiquitin aggregates were found in the DAergic neurons of the SNc and neurites in the STR. In addition, we identified alpha-syn aggregates in neurons of the locus coeruleus and cingulate cortex. No loss of motor neurons in the spinal cord was found after chronic consumption of cycad flour. In an organotypic slice culture of the rat SN and the striatum, an organic extract of cycad causes a selective loss of dopamine neurons and alpha-syn aggregates in the SN.Cycad-fed rats exhibit progressive behavioral, biochemical, and histological hallmarks of parkinsonism, coupled with a lack of fatality.

Published

2010

30. Cell-Based Therapy in TBI: Magnetic Retention of Neural Stem Cells In Vivo

Author

Paul Yarowsky, Wei-Bin Shen, Orest Tsymbalyuk, Sarah L. J. Michel, Adam C. Puche, Rao P. Gullapalli, J. Marc Simard, Natalya Tsymbalyuk, Aaron M Smith, Su Xu, Paul S. Fishman, Roger J. Mullins, Celine Plachez, and Deborah Yarnell

Subjects

0301 basic medicine, Male, Pathology, medicine.medical_specialty, Programmed cell death, Necrosis, Traumatic brain injury, medicine.medical_treatment, Biomedical Engineering, lcsh:Medicine, Rats, Sprague-Dawley, 03 medical and health sciences, Magnetics, 0302 clinical medicine, Neural Stem Cells, In vivo, Brain Injuries, Traumatic, medicine, Animals, Humans, Inflammation, Transplantation, medicine.diagnostic_test, Cell Death, business.industry, Rhodamines, lcsh:R, Magnetic resonance imaging, Cell Biology, Stem-cell therapy, medicine.disease, Magnetic Resonance Imaging, Neural stem cell, 030104 developmental biology, Magnetic Fields, Stem cell, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

Stem cell therapy is under active investigation for traumatic brain injury (TBI). Noninvasive stem cell delivery is the preferred method, but retention of stem cells at the site of injury in TBI has proven challenging and impacts effectiveness. To investigate the effects of applying a magnetic field on cell homing and retention, we delivered human neuroprogenitor cells (hNPCs) labeled with a superparamagnetic nanoparticle into post-TBI animals in the presence of a static magnetic field. We have previously devised a method of loading hNPCs with ultrasmall superparamagnetic iron oxide (USPIO) nanoparticles Molday ION Rhodamine B (MIRB™). Labeling of hNPCs (MIRB-hNPCs) does not affect hNPC viability, proliferation, or differentiation. The 0.6 tesla (T) permanent magnet was placed ~4 mm above the injured parietal cortex prior to intracarotid injection of 4 × 104 MIRB-hNPCs. Fluorescence imaging, Perls' Prussian blue histochemistry, immunocytochemistry with SC121, a human-specific antibody, and T2-weighted magnetic resonance imaging ex vivo revealed there was increased homing and retention of MIRB-hNPCs in the injured cortex as compared to the control group in which MIRB-hNPCs were injected in the absence of a static magnetic field. Fluoro-Jade C staining and immunolabeling with specific markers confirmed the viability status of MIRB-hNPCs posttransplantation. These results show that increased homing and retention of MIRB-hNPCs post-TBI by applying a static magnetic field is a promising technique to deliver cells into the CNS for treatment of neurological injuries and neurodegenerative diseases.

Published

2015

31. SIRB, sans iron oxide rhodamine B, a novel cross-linked dextran nanoparticle, labels human neuroprogenitor and SH-SY5Y neuroblastoma cells and serves as a USPIO cell labeling control

Author

Wei-Bin, Shen, Dennis E, Vaccaro, Paul S, Fishman, Ernest V, Groman, and Paul, Yarowsky

Subjects

Staining and Labeling, Cell Survival, Rhodamines, Cell Differentiation, Dextrans, Magnetic Resonance Imaging, Neuroblastoma, Cross-Linking Reagents, Neural Stem Cells, Humans, Nanoparticles, Magnetite Nanoparticles, Cells, Cultured, Cell Proliferation

Abstract

This is the first report of the synthesis of a new nanoparticle, sans iron oxide rhodamine B (SIRB), an example of a new class of nanoparticles. SIRB is designed to provide all of the cell labeling properties of the ultrasmall superparamagnetic iron oxide (USPIO) nanoparticle Molday ION Rhodamine B (MIRB) without containing the iron oxide core. MIRB was developed to label cells and allow them to be tracked by MRI or to be manipulated by magnetic gradients. SIRB possesses a similar size, charge and cross-linked dextran coating as MIRB. Of great interest is understanding the biological and physiological changes in cells after they are labeled with a USPIO. Whether these effects are due to the iron oxide buried within the nanoparticle or to the surface coating surrounding the iron oxide core has not been considered previously. MIRB and SIRB represent an ideal pairing of nanoparticles to identify nanoparticle anatomy responsible for post-labeling cytotoxicity. Here we report the effects of SIRB labeling on the SH-SY5Y neuroblastoma cell line and primary human neuroprogenitor cells (hNPCs). These effects are contrasted with the effects of labeling SH-SY5Y cells and hNPCs with MIRB. We find that SIRB labeling, like MIRB labeling, (i) occurs without the use of transfection reagents, (ii) is packaged within lysosomes distributed within cell cytoplasm, (iii) is retained within cells with no loss of label after cell storage, and (iv) does not alter cellular viability or proliferation, and (v) SIRB labeled hNPCs differentiate normally into neurons or astrocytes. Copyright © 2016 John WileySons, Ltd.

Published

2015

32. 5th International Symposium on Focused Ultrasound

Author

Aerospace and Ocean Engineering, Abounader, Roger, Abraham, Christopher, Adema, Gosse, Agrawal, Punit, Airan, Raag, Aleman, Dionne, Alexander, Phillip, Alkins, Ryan, Alnazeer, Moez, Altman, Michael, Aly, Amirah, Amaral, Joao G., Amrahli, Maral, Amraoui, Sana, Andarawewa, Kumari, Andriyakhina, Yulia, Angstadt, Mary, Ankou, Bénédicte, Arias, Ana C., Arvanitis, Costas, Asadnia, Kiana, Aubert, Isabelle, Aubry, Jean-Francois, Aurup, Christian, Bader, Kenneth, Badr, Lena, Baek, Hongchae, Barbato, Gaetano, Beccaria, Kevin, Bellorofonte, Carlo, Benson, Lee, Bernus, Olivier, Berriet, Rémi, Bertolina, Jim, Beskin, Viktoriya, Bessière, Francis, Bethune, Allison, Bezzi, Mario, Bond, Aaron, Bonomo, Guido, Borowsky, Alexander, Borys, Nicolas, Böttcher, Joachim, Bouley, Donna, Bour, Pierre, Bourekas, Eric, Brenin, David, Brokman, Omer, Brosh, Inbar, Buckner, Andrew, Bullock, Timothy, Cafarelli, Andrea, Cahill, Jessica, Camarena, Francisco, Camelo-Piragua, Sandra, Campbell, Benjamin, Campbell, Fiona, Cannata, Jon, Canney, Michael, Carlson, Roy, Carneiro, Antonio, Carpentier, Alexandre, Catheline, Stefan, Cavin, Ian, Cesana, Claudio, Chabok, Hamid R., Chamanara, Marzieh, Chang, Jin H., Chang, Won S., Changizi, Barbara, Chapelon, Jean Y., Chaplin, Vandiver, Chapman, Martin, Chaudhary, Neeraj, Chaussy, Christian, Chen, Cherry, Chen, Johnny, Chen, Wohsing, Chen, Xiaoming, Chevalier, Philippe, Chiou, George, Chisholm, Alexander, Christofferson, Ivy, Chung, Hyun H., Ciuti, Gastone, Clement, Gregory, Cooper, Mark, Corea, Joseph, Corso, Cristiano, Cosman, Josh, Coughlin, Dezba, Crake, Calum, Cunitz, Bryan, Curiel, Laura, Curley, Colleen T., Czarnota, Gregory, Dababou, Susan, Dallapiazza, Robert, de Bever, Joshua, de Jager, Bram, de Ruiter, Joost, de Senneville, Baudouin D., Deckers, Roel, Delattre, Jean-Yves, den Brok, Martijn, Dhanaliwala, Ali, Diodato, Alessandro, Dixon, Adam, Donner, Elizabeth, Downs, Matthew, Du, Zhongmin, Dubois, Rémi, Dupre, Aurelien, Eikelenboom, Dylan, Elias, W. J., Ellens, Nicholas, Endre, Ruby, Eran, Ayelet, Erasmus, Hans-Peter, Everstine, Ashli, Farahani, Keyvan, Farrer, Alexis, Farry, Justin, Federau, Christian, Feng, Xue, Ferrer, Cyril, Ferrera, Vincent, Fishman, Paul, Foley, Jessica, Frenkel, Victor, Fütterer, Jurgen, Gach, H. M., Gandhi, Dheeraj, Gertner, Michael, Goldsher, Dorit, Gorgone, Alessandro, Greillier, Paul, Griesenauer, Rebekah, Grissom, William, Grondin, Julien, Guha, Chandan, Gulati, Amitabh, Gullapalli, Rao, Guo, Sijia, Gupta, Samit, Gurm, Hitinder, Gwinn, Ryder, Hadley, Rock, Haïssaguerre, Michel, Hammoud, Dima, Hananel, Arik, Hargrove, Amelia, Hatch, Robert, Haworth, Kevin, Hazan, Eilon, He, Ye, Heemels, Maurice, Heerschap, Arend, Hilas, Elaine, Hoang-Xuan, Khe, Hocini, Mélèze, Hodaie, Mojgan, Hofmann, Denis, Holland, Christy, Hoogenboom, Martijn, Hopyan, Sevan, Hossack, John, Houdouin, Alexandre, Hsu, Po-Hung, Hu, Jim, Hurwitz, Mark, Huss, Diane, Hwang, Chang-il, Hwang, Joo H., Idbaih, Ahmed, Ikeuchi, Masahiko, Ingham, Elizabeth, Ives, Kimberly, Izumi, Masashi, Jackson-Lewis, Vernice, Janát-Amsbury, Margit, Jang, Kee W., Jedruszczuk, Kathleen, Jiménez-Gambín, Sergio, Jiménez, Noé, Johnson, Sara, Jonathan, Sumeeth, Joy, Joyce, Jung, Hyun H., Jung, Na Y., Kahn, Itamar, Kamimura, Hermes, Kamrava, Seyed K., Kang, Jeeun, Kang, Kook J., Kang, Soo Y., Kao, Yi-tzu, Katti, Prateek, Kawasaki, Motohiro, Kaye, Elena, Keupp, Jochen, Kim, AeRang, Kim, Harry, Kim, Hyun-Chul, Kim, Hyuncheol, Kim, Hyungmin, Kim, Min S., Kim, Namho, Kiyasu, Katsuhito, Kneepkens, Esther, Knopp, Michael, Kobus, Thiele, Koral, Korgun, Kreider, Wayne, Krishna, Vibhor, Krug, Roland, Krupa, Steve, Kuo, Chia-Chun, Kwiecinski, Wojciech, Lacoste, Romain, Lam, Heather, Lamberti-Pasculli, Maria, Lang, Brian, Larner, James, Larrabee, Zachary, Leach, J. K., LeBlang, Suzanne, Leclercq, Delphine, Lee, Hak J., Lee, Jong-Hwan, Lehericy, Stéphane, Leighton, Wan, Leung, Steven, Lewis, Bobbi, Lewis, Matthew, Li, Dawei, Linn, Sabine, Lipsman, Nir, Liu, Hao-Li, Liu, Jingfei, Lopes, M. B., Lotz, Jeff, Lu, Xin, Lundt, Jonathan, Luo, Xi, Lustgarten, Lior, Lustig, Micheal, Macoskey, Jonathan, Madore, Bruno, Maev, Roman, Magat, Julie, Maimbourg, Guillaume, Maimon, Noam, Mainprize, Todd, Malayer, Jerry, Maples, Danny, Marquet, Fabrice, Marrocchio, Cristina, Marx, Mike, Mastorakos, Panagiotis, Mauri, Giovanni, McLean, Hailey, McMichael, John, Mead, Brian P., Melodelima, David, Melot-Dusseau, Sandrine, Menciassi, Arianna, Merrill, Robb, Meyer, Joshua, Midiri, Massimo, Miga, Michael, Migliore, Ilaria G., Miller, Eric, Minalga, Emilee, Moon, Hyungwon, Moore, David, Mourad, Pierre, Mouratidis, Petros, Mueller, Michael, Mugler, John, Muller, Sébastien, Namba, Hirofumi, Naor, Omer, Nassar, Maria, Nazai, Navid, Negron, Karina, Negussie, Ayele, Nguyen, Thai-Son, Nicolay, Klaas, Nikolaeva, Anastasia V., Oetgen, Matthew, Olive, Kenneth, Olumolade, Oluyemi, Orsi, Franco, Owens, Gabe, Ozilgen, Arda, Padegimas, Linas, Palermo, Carmine, Pan, Chia-Hsin, Pandey, Aditya, Papadakis, Georgios, Park, Chang K., Park, Sang M., Parker, Jonathon, Parvizi, Mohammad H., Pascal-Tenorio, Aurea, Patel, Janish, Patz, Sam, Payen, Thomas, Perich, Eloi, Pernot, Mathieu, Perol, David, Perry, James, Pillarisetty, Venu, Pioche, Mathieu, Pizzuto, Matthew, Plaksin, Michael, Plata, Juan, Price, Karl, Prince, Jessica, Przedborski, Serge, Quinones-Hinojosa, Alfredo, Ramachandran, Akhilesh, Ranjan, Ashish, Ravikumar, Vinod, Reichenbach, Juergen, Repasky, Elizabeth, Rezai, Ali, Ritter, Philippe, Rivoire, Michel, Rochman, Carrie, Rosenberg, Jarrett, Rosnitskiy, Pavel B., Ruiz, Antonio, Sahgal, Arjun, Samiotaki, Gesthimani, Sanghvi, Narendra, Santin, Mathieu D., Santos, Domiciano, Sasaki, Noboru, Sastra, Steve, Schade, George, Schall, Jeffrey, Schlesinger, Ilana, Schmitt, Paul, Schwaab, Julia, Scionti, Stephen, Scipione, Roberto, Scoarughi, Gian L., Scott, Serena, Sebeke, Lukas, Seifabadi, Reza, Seo, Jai, Sesenoglu-Laird, Ozge, Shah, Binit, Shahriari, Kian, Shaikh, Sumbul, Shea, Jill, Shi, Jiaqi, Shim, Jenny, Shinkov, Alexander, Shuman, Jillian, Silvestrini, Matthew, Sim, Changbeom, Sin, Vivian, Sinai, Alon, Singh, Manoj, Sinilshchikov, Ilya, Skalina, Karin, Slingluff, Craig, So, Po-Wah, Solomon, Stephen, Son, Keon H., Sperling, Scott, Stein, Ruben, Stein, Sherman, Stevens, Aaron, Stimec, Jennifer, Storm, Gert, Straube, William, Suelmann, Britt, Sutton, Jonathan, Svedin, Bryant, Takemasa, Ryuichi, Takiguchi, Mitsuyoshi, Tam, Emily, Tan, Jeremy, Tang, Xinyan, Tanter, Mickael, Tebebi, Pamela, Tehrani, Seruz, Temple, Michael, Teofilovic, Dejan, ter Haar, Gail, Terzi, Marina E., Thueroff, Stefan, Timbie, Kelsie, Tognarelli, Selene, Tretbar, Steffen, Trudeau, Maureen, Tsai, Yi-Chieh, Tsysar, Sergey A., Tucci, Samantha, Tuveson, David, Ushida, Takahiro, Vaessen, Paul, Vaillant, Fanny, Van Arsdell, Glen, van Breugel, Johanna, Van der Jeugd, Anneke, Van der Wall, Elsken, van Diest, Paul, van Stralen, Marijn, Varano, Gianluca, Velat, Manuela, Vidal-Jove, Joan, Vigna, Paolo D., Vignot, Alexandre, Vincenot, Jeremy, Vykhodtseva, Natalia, Wang, Bin, Wang, Han, Wang, Kevin, Wang, Qi, Wang, Qingguo, Wang, Shengping, Wang, Yak-Nam, Wang, Zhaorui, Wardlow, Rachel, Warren, Amy, Waszczak, Barbara, Watson, Katherine, Webb, Taylor, Wei-Bin, Shen, Wei, Kuo-Chen, Weiss, Steffen, Weissler, Yoni, Werner, Beat, Wesseling, Pieter, Williams, Noelle, Wilson, Emmanuel, Wintermark, Max, Witkamp, Arjen, Wong, Carlos, Wu, Jing-Fu, Wydra, Adrian, Xu, Alexis, Xu, Doudou, Xu, Su, Yang, Georgiana, Yang, Nai-Yi, Yao, Chen, Yarowsky, Paul, Ye, Patrick P., Yuldashev, Petr, Zaaroor, Menashe, Zachiu, Cornel, Zahos, Peter, Zangos, Stephan, Zhang, Dandan, Zhang, Hua, Zhang, Jimin, Zhang, Junhai, Zhang, Xi, Zhao, Li, Zhong, Pei, Zhuo, Jiachen, Zidowitz, Stephan, Zinke, Wolf, Zorgani, Ali, Aerospace and Ocean Engineering, Abounader, Roger, Abraham, Christopher, Adema, Gosse, Agrawal, Punit, Airan, Raag, Aleman, Dionne, Alexander, Phillip, Alkins, Ryan, Alnazeer, Moez, Altman, Michael, Aly, Amirah, Amaral, Joao G., Amrahli, Maral, Amraoui, Sana, Andarawewa, Kumari, Andriyakhina, Yulia, Angstadt, Mary, Ankou, Bénédicte, Arias, Ana C., Arvanitis, Costas, Asadnia, Kiana, Aubert, Isabelle, Aubry, Jean-Francois, Aurup, Christian, Bader, Kenneth, Badr, Lena, Baek, Hongchae, Barbato, Gaetano, Beccaria, Kevin, Bellorofonte, Carlo, Benson, Lee, Bernus, Olivier, Berriet, Rémi, Bertolina, Jim, Beskin, Viktoriya, Bessière, Francis, Bethune, Allison, Bezzi, Mario, Bond, Aaron, Bonomo, Guido, Borowsky, Alexander, Borys, Nicolas, Böttcher, Joachim, Bouley, Donna, Bour, Pierre, Bourekas, Eric, Brenin, David, Brokman, Omer, Brosh, Inbar, Buckner, Andrew, Bullock, Timothy, Cafarelli, Andrea, Cahill, Jessica, Camarena, Francisco, Camelo-Piragua, Sandra, Campbell, Benjamin, Campbell, Fiona, Cannata, Jon, Canney, Michael, Carlson, Roy, Carneiro, Antonio, Carpentier, Alexandre, Catheline, Stefan, Cavin, Ian, Cesana, Claudio, Chabok, Hamid R., Chamanara, Marzieh, Chang, Jin H., Chang, Won S., Changizi, Barbara, Chapelon, Jean Y., Chaplin, Vandiver, Chapman, Martin, Chaudhary, Neeraj, Chaussy, Christian, Chen, Cherry, Chen, Johnny, Chen, Wohsing, Chen, Xiaoming, Chevalier, Philippe, Chiou, George, Chisholm, Alexander, Christofferson, Ivy, Chung, Hyun H., Ciuti, Gastone, Clement, Gregory, Cooper, Mark, Corea, Joseph, Corso, Cristiano, Cosman, Josh, Coughlin, Dezba, Crake, Calum, Cunitz, Bryan, Curiel, Laura, Curley, Colleen T., Czarnota, Gregory, Dababou, Susan, Dallapiazza, Robert, de Bever, Joshua, de Jager, Bram, de Ruiter, Joost, de Senneville, Baudouin D., Deckers, Roel, Delattre, Jean-Yves, den Brok, Martijn, Dhanaliwala, Ali, Diodato, Alessandro, Dixon, Adam, Donner, Elizabeth, Downs, Matthew, Du, Zhongmin, Dubois, Rémi, Dupre, Aurelien, Eikelenboom, Dylan, Elias, W. J., Ellens, Nicholas, Endre, Ruby, Eran, Ayelet, Erasmus, Hans-Peter, Everstine, Ashli, Farahani, Keyvan, Farrer, Alexis, Farry, Justin, Federau, Christian, Feng, Xue, Ferrer, Cyril, Ferrera, Vincent, Fishman, Paul, Foley, Jessica, Frenkel, Victor, Fütterer, Jurgen, Gach, H. M., Gandhi, Dheeraj, Gertner, Michael, Goldsher, Dorit, Gorgone, Alessandro, Greillier, Paul, Griesenauer, Rebekah, Grissom, William, Grondin, Julien, Guha, Chandan, Gulati, Amitabh, Gullapalli, Rao, Guo, Sijia, Gupta, Samit, Gurm, Hitinder, Gwinn, Ryder, Hadley, Rock, Haïssaguerre, Michel, Hammoud, Dima, Hananel, Arik, Hargrove, Amelia, Hatch, Robert, Haworth, Kevin, Hazan, Eilon, He, Ye, Heemels, Maurice, Heerschap, Arend, Hilas, Elaine, Hoang-Xuan, Khe, Hocini, Mélèze, Hodaie, Mojgan, Hofmann, Denis, Holland, Christy, Hoogenboom, Martijn, Hopyan, Sevan, Hossack, John, Houdouin, Alexandre, Hsu, Po-Hung, Hu, Jim, Hurwitz, Mark, Huss, Diane, Hwang, Chang-il, Hwang, Joo H., Idbaih, Ahmed, Ikeuchi, Masahiko, Ingham, Elizabeth, Ives, Kimberly, Izumi, Masashi, Jackson-Lewis, Vernice, Janát-Amsbury, Margit, Jang, Kee W., Jedruszczuk, Kathleen, Jiménez-Gambín, Sergio, Jiménez, Noé, Johnson, Sara, Jonathan, Sumeeth, Joy, Joyce, Jung, Hyun H., Jung, Na Y., Kahn, Itamar, Kamimura, Hermes, Kamrava, Seyed K., Kang, Jeeun, Kang, Kook J., Kang, Soo Y., Kao, Yi-tzu, Katti, Prateek, Kawasaki, Motohiro, Kaye, Elena, Keupp, Jochen, Kim, AeRang, Kim, Harry, Kim, Hyun-Chul, Kim, Hyuncheol, Kim, Hyungmin, Kim, Min S., Kim, Namho, Kiyasu, Katsuhito, Kneepkens, Esther, Knopp, Michael, Kobus, Thiele, Koral, Korgun, Kreider, Wayne, Krishna, Vibhor, Krug, Roland, Krupa, Steve, Kuo, Chia-Chun, Kwiecinski, Wojciech, Lacoste, Romain, Lam, Heather, Lamberti-Pasculli, Maria, Lang, Brian, Larner, James, Larrabee, Zachary, Leach, J. K., LeBlang, Suzanne, Leclercq, Delphine, Lee, Hak J., Lee, Jong-Hwan, Lehericy, Stéphane, Leighton, Wan, Leung, Steven, Lewis, Bobbi, Lewis, Matthew, Li, Dawei, Linn, Sabine, Lipsman, Nir, Liu, Hao-Li, Liu, Jingfei, Lopes, M. B., Lotz, Jeff, Lu, Xin, Lundt, Jonathan, Luo, Xi, Lustgarten, Lior, Lustig, Micheal, Macoskey, Jonathan, Madore, Bruno, Maev, Roman, Magat, Julie, Maimbourg, Guillaume, Maimon, Noam, Mainprize, Todd, Malayer, Jerry, Maples, Danny, Marquet, Fabrice, Marrocchio, Cristina, Marx, Mike, Mastorakos, Panagiotis, Mauri, Giovanni, McLean, Hailey, McMichael, John, Mead, Brian P., Melodelima, David, Melot-Dusseau, Sandrine, Menciassi, Arianna, Merrill, Robb, Meyer, Joshua, Midiri, Massimo, Miga, Michael, Migliore, Ilaria G., Miller, Eric, Minalga, Emilee, Moon, Hyungwon, Moore, David, Mourad, Pierre, Mouratidis, Petros, Mueller, Michael, Mugler, John, Muller, Sébastien, Namba, Hirofumi, Naor, Omer, Nassar, Maria, Nazai, Navid, Negron, Karina, Negussie, Ayele, Nguyen, Thai-Son, Nicolay, Klaas, Nikolaeva, Anastasia V., Oetgen, Matthew, Olive, Kenneth, Olumolade, Oluyemi, Orsi, Franco, Owens, Gabe, Ozilgen, Arda, Padegimas, Linas, Palermo, Carmine, Pan, Chia-Hsin, Pandey, Aditya, Papadakis, Georgios, Park, Chang K., Park, Sang M., Parker, Jonathon, Parvizi, Mohammad H., Pascal-Tenorio, Aurea, Patel, Janish, Patz, Sam, Payen, Thomas, Perich, Eloi, Pernot, Mathieu, Perol, David, Perry, James, Pillarisetty, Venu, Pioche, Mathieu, Pizzuto, Matthew, Plaksin, Michael, Plata, Juan, Price, Karl, Prince, Jessica, Przedborski, Serge, Quinones-Hinojosa, Alfredo, Ramachandran, Akhilesh, Ranjan, Ashish, Ravikumar, Vinod, Reichenbach, Juergen, Repasky, Elizabeth, Rezai, Ali, Ritter, Philippe, Rivoire, Michel, Rochman, Carrie, Rosenberg, Jarrett, Rosnitskiy, Pavel B., Ruiz, Antonio, Sahgal, Arjun, Samiotaki, Gesthimani, Sanghvi, Narendra, Santin, Mathieu D., Santos, Domiciano, Sasaki, Noboru, Sastra, Steve, Schade, George, Schall, Jeffrey, Schlesinger, Ilana, Schmitt, Paul, Schwaab, Julia, Scionti, Stephen, Scipione, Roberto, Scoarughi, Gian L., Scott, Serena, Sebeke, Lukas, Seifabadi, Reza, Seo, Jai, Sesenoglu-Laird, Ozge, Shah, Binit, Shahriari, Kian, Shaikh, Sumbul, Shea, Jill, Shi, Jiaqi, Shim, Jenny, Shinkov, Alexander, Shuman, Jillian, Silvestrini, Matthew, Sim, Changbeom, Sin, Vivian, Sinai, Alon, Singh, Manoj, Sinilshchikov, Ilya, Skalina, Karin, Slingluff, Craig, So, Po-Wah, Solomon, Stephen, Son, Keon H., Sperling, Scott, Stein, Ruben, Stein, Sherman, Stevens, Aaron, Stimec, Jennifer, Storm, Gert, Straube, William, Suelmann, Britt, Sutton, Jonathan, Svedin, Bryant, Takemasa, Ryuichi, Takiguchi, Mitsuyoshi, Tam, Emily, Tan, Jeremy, Tang, Xinyan, Tanter, Mickael, Tebebi, Pamela, Tehrani, Seruz, Temple, Michael, Teofilovic, Dejan, ter Haar, Gail, Terzi, Marina E., Thueroff, Stefan, Timbie, Kelsie, Tognarelli, Selene, Tretbar, Steffen, Trudeau, Maureen, Tsai, Yi-Chieh, Tsysar, Sergey A., Tucci, Samantha, Tuveson, David, Ushida, Takahiro, Vaessen, Paul, Vaillant, Fanny, Van Arsdell, Glen, van Breugel, Johanna, Van der Jeugd, Anneke, Van der Wall, Elsken, van Diest, Paul, van Stralen, Marijn, Varano, Gianluca, Velat, Manuela, Vidal-Jove, Joan, Vigna, Paolo D., Vignot, Alexandre, Vincenot, Jeremy, Vykhodtseva, Natalia, Wang, Bin, Wang, Han, Wang, Kevin, Wang, Qi, Wang, Qingguo, Wang, Shengping, Wang, Yak-Nam, Wang, Zhaorui, Wardlow, Rachel, Warren, Amy, Waszczak, Barbara, Watson, Katherine, Webb, Taylor, Wei-Bin, Shen, Wei, Kuo-Chen, Weiss, Steffen, Weissler, Yoni, Werner, Beat, Wesseling, Pieter, Williams, Noelle, Wilson, Emmanuel, Wintermark, Max, Witkamp, Arjen, Wong, Carlos, Wu, Jing-Fu, Wydra, Adrian, Xu, Alexis, Xu, Doudou, Xu, Su, Yang, Georgiana, Yang, Nai-Yi, Yao, Chen, Yarowsky, Paul, Ye, Patrick P., Yuldashev, Petr, Zaaroor, Menashe, Zachiu, Cornel, Zahos, Peter, Zangos, Stephan, Zhang, Dandan, Zhang, Hua, Zhang, Jimin, Zhang, Junhai, Zhang, Xi, Zhao, Li, Zhong, Pei, Zhuo, Jiachen, Zidowitz, Stephan, Zinke, Wolf, and Zorgani, Ali

Published

2016

33. Release of amines from acidified stores following accumulation by Transport-P

Author

Wei-Bin Shen and S Al-Damluji

Subjects

Pharmacology, biology, Organic base, Chemistry, ATPase, Monensin, chemistry.chemical_compound, Biochemistry, Desipramine, biology.protein, Extracellular, medicine, Prazosin, Electrochemical gradient, Intracellular, medicine.drug

Abstract

Transport-P is an uptake process for amines in peptidergic neurones of the hypothalamus. It differs from other uptake processes by its anatomical location in post-synaptic neurones, its functional properties and by the structure of its ligands. Transport-P accumulates amines in intracellular vesicles, derives its energy from the electrochemical proton gradient and is linked to vacuolar-type ATPase (V-ATPase). Transport-P is blocked by antidepressants. We have now studied the release of amines following uptake by Transport-P in a cell line of hypothalamic peptidergic neurones. Release of prazosin was not inhibited by the antidepressant desipramine; as Transport-P is blocked by desipramine, this indicated that amines are released by a mechanism which is independent of Transport-P. Release of prazosin was sensitive to temperature and conformed to the Arrhenius equation. Release was minimal in the range 0 – 25°C but accelerated exponentially at higher temperatures up to 33°C. The activation energy for the release of prazosin is 83.1 kJ mol−1, corresponding to a temperature quotient (Q10) value of 3. Release was accelerated by the organic base chloroquine, the ionophore monensin, bafilomycinA1 which inhibits V-ATPase and by increasing extracellular pH. Thus, retention of prazosin requires an intracellular proton gradient which is generated by V-ATPase. Fluorescence microscopy demonstrated that release of BODIPY FL prazosin was temperature dependent and was accelerated by chloroquine and monensin. Thus, following uptake by Transport-P, amines are accumulated in acidified intracellular stores. Their retention in peptidergic neurones requires intracellular acidity. The amines are released by a temperature-dependent process which is resistant to antidepressants. British Journal of Pharmacology (2001) 132, 851–860; doi:10.1038/sj.bjp.0703872

Published

2001

34. α1Badrenergic receptors in gonadotrophin-releasing hormone neurones: relation to Transport-P

Author

S Al-Damluji, Eric A. Barnard, Wei-Bin Shen, and S White

Subjects

Pharmacology, medicine.medical_specialty, Adrenergic receptor, Adrenergic, Gonadotropin-releasing hormone, Peptide hormone, Biology, Norepinephrine, Endocrinology, Internal medicine, cardiovascular system, medicine, Prazosin, Receptor, Alpha-1 adrenergic receptor, medicine.drug

Abstract

Peptidergic neurones accumulate amines via an unusual uptake process, designated Transport-P. [3H]-prazosin binds to α1 adrenoceptors on these cells and is displaceable by unlabelled prazosin in concentrations up to 10−7 M. However, at greater concentrations of prazosin, there is a paradoxical accumulation of [3H]-prazosin which we have attributed to Transport-P. Uptake of prazosin via Transport-P is detectable at 10−10 M prazosin concentration, is linear up to 10−7 M and at greater concentrations becomes non-linear. In contrast, in noradrenergic neurones, noradrenaline uptake is linear and saturates above 10−7 M. In noradrenergic neurones and in non-neuronal cells, there is no uptake of prazosin in concentrations up to 10−6 M, suggesting that Transport-P is a specialised function of peptidergic neurones. Using a mouse peptidergic (gonadotrophin-releasing hormone, GnRH) neuronal cell line which possesses Transport-P, we have studied the interaction of α1 adrenoceptors with Transport-P. Polymerase chain reactions and DNA sequencing of the products demonstrated that only the α1B sub-type of adrenoceptors is present in GnRH cells. In COS cells transfected with α1b adrenoceptor cDNA and in DDT1 MF-2 cells which express native α1B adrenoceptors, [3H]-prazosin was displaced by unlabelled prazosin in a normal equilibrium process, with no prazosin paradox in concentrations up to 10−6 M. In DDT1 MF-2 cells, [3H]-prazosin was displaced likewise by a series of α1 adrenergic agonists, none of which increased the binding of [3H]-prazosin. Hence, the prazosin paradox is not due to some function of α1 adrenoceptors, such as internalization of ligand-receptor complexes. In neurones which possess Transport-P, transfection with α1b adrenoceptor cDNA resulted in over-expression of α1B adrenoceptors, but the prazosin paradox was unaltered. Thus, α1 adrenoceptors and Transport-P mediate distinct functions in peptidergic neurones. British Journal of Pharmacology (2001) 132, 336–344; doi:10.1038/sj.bjp.0703781

Published

2001

35. Human neural progenitor cells retain viability, phenotype, proliferation, and lineage differentiation when labeled with a novel iron oxide nanoparticle, Molday ION Rhodamine B

Author

Amanda Chan, Adam C. Puche, Wei-Bin Shen, Paul S. Fishman, Paul Yarowsky, Celine Plachez, and Deborah Yarnell

Subjects

Cell, Biophysics, Short Report, Pharmaceutical Science, Bioengineering, Biology, Cell Physiological Phenomena, Biomaterials, Rhodamine, chemistry.chemical_compound, Neural Stem Cells, International Journal of Nanomedicine, Drug Discovery, medicine, Humans, human, Progenitor cell, ferumoxides, Coloring Agents, Magnetite Nanoparticles, Cells, Cultured, Staining and Labeling, Rhodamines, Organic Chemistry, Mesenchymal stem cell, General Medicine, Transfection, USPIO, Neural stem cell, Cell biology, Transplantation, medicine.anatomical_structure, Phenotype, MION, chemistry, Immunology, SC121 antibody, Stem cell, toxicology

Abstract

Wei-Bin Shen,1,2 Celine Plachez,2,3 Amanda Chan,4 Deborah Yarnell,1 Adam C Puche,3 Paul S Fishman,1,5 Paul Yarowsky1,21Research Service, VA Maryland Health Care System, Baltimore, MD, USA; 2Department of Pharmacology, University of Maryland School of Medicine, Baltimore, MD, USA; 3Department of Anatomy and Neurobiology, University of Maryland School of Medicine, Baltimore, MD, USA; 4Notre Dame of Maryland School of Pharmacy, Baltimore, MD, USA; 5Department of Neurology, University of Maryland School of Medicine, Baltimore, MD, USAAbstract: Ultrasmall superparamagnetic iron-oxide particles (USPIOs) loaded into stem cells have been suggested as a way to track stem cell transplantation with magnetic resonance imaging, but the labeling, and post-labeling proliferation, viability, differentiation, and retention of USPIOs within the stem cells have yet to be determined for each type of stem cell and for each type of USPIO. Molday ION Rhodamine B™ (BioPAL, Worcester, MA, USA) (MIRB) has been shown to be a USPIO labeling agent for mesenchymal stem cells, glial progenitor cells, and stem cell lines. In this study, we have evaluated MIRB labeling in human neuroprogenitor cells and found that human neuroprogenitor cells are effectively labeled with MIRB without use of transfection reagents. Viability, proliferation, and differentiation properties are unchanged between MIRB-labeled neuroprogenitors cells and unlabeled cells. Moreover, MIRB-labeled human neuroprogenitor cells can be frozen, thawed, and replated without loss of MIRB or even without loss of their intrinsic biology. Overall, those results show that MIRB has advantageous properties that can be used for cell-based therapy.Keywords: ferumoxides, USPIO, MION, neural stem cells, SC121 antibody, human, toxicology

Published

2013

36. Castration rapidly decreases hypothalamic γ-aminobutyric acidergic neuronal activity in both male and female rats

Author

Michael Selmanoff, Ju-Ren He, David R. Grattan, Wei-Bin Shen, Robin V. Searles, and Mi-Jeong Yoo

Subjects

Male, medicine.medical_specialty, Hypothalamus, Biology, Rats, Sprague-Dawley, chemistry.chemical_compound, GABA transaminase, Internal medicine, medicine, Animals, Premovement neuronal activity, Castration, Molecular Biology, gamma-Aminobutyric Acid, Neurons, Sex Characteristics, General Neuroscience, Luteinizing Hormone, Lordosis behavior, Diagonal band of Broca, Rats, Stria terminalis, Endocrinology, medicine.anatomical_structure, chemistry, GABAergic, Female, Neurology (clinical), Developmental Biology

Abstract

The postcastration LH response is greater and somewhat more rapid in male than female rats. We have previously demonstrated that hypothalamic γ-aminobutyric acid (GABA)ergic neuronal activity decreases following gonadectomy in male rats. To investigate whether these same hypothalamic GABA neurons decrease their activity postcastration in female rats, and whether more rapid and or greater postcastration decreases occur in male rats, we determined the timing and magnitude of the postcastration decreases in GABA turnover which are associated with the sexually dimorphic postcastration LH response. Adult male and 4-day cycling female rats were castrated between 0800 and 1000 h (females ovariectomized on diestrus day 1). Serum LH levels increased significantly by 12 h postcastration in both males and females with the magnitude of the increases being 6.2-fold in males and 2.8-fold in females. GABA turnover was determined in 16 microdissected brain structures by the GABA transaminase inhibition method at 0 h (sham-operated controls), 6 h, 12 h and 1, 2, 4 and 6 days postcastration. In male rats, in the diagonal band of Broca at the level of the organum vasculosum of the lamina terminalis [DBB(ovlt)], the rate of GABA turnover decreased significantly already by 6 h postcastration compared with the 0 h controls, and remained suppressed through 6 days. This rapid down regulation of DBB(ovlt) GABAergic neurons also occurred in female rats, however, the duration of the decrease was not as prolonged as in male rats. Similar changes occurred in the tuberoinfundibular GABAergic (TIGA) neurons projecting to the median eminence in both males and females. Down regulation of these GABAergic neurons precedes or is coincident with increased postcastration LH secretion in both sexes, and the duration of the decreases is consistent with the less robust postcastration LH response in female rats. In addition, the rate of GABA turnover decreased after castration in the interstitial (bed) nucleus of the stria terminalis, ventral aspect (INSTv), the medial preoptic nucleus, dorsomedial aspect (MPNdm) and the ventromedial nucleus, ventrolateral aspect (VMNvl) in male rats, and in the INSTv and VMNvl of female rats, while there was no effect of castration in other hypothalamic regions or control structures. The result in the female VMNvl is consistent with reports that GABA facilitates lordosis behavior in this hypothalamic structure. These findings are consistent with the hypothesis that discrete hypothalamic populations of sex steroid-sensitive GABAergic neurons mediate the postcastration LH responses in both male and female rats, and may underlie other sexually dimorphic adult phenotypes such as sex behavior.

Published

2000

37. 5th International Symposium on Focused Ultrasound

Author

Zaaroor, Menashe, primary, Sinai, Alon, additional, Goldsher, Dorit, additional, Eran, Ayelet, additional, Nassar, Maria, additional, Schlesinger, Ilana, additional, Parker, Jonathon, additional, Ravikumar, Vinod, additional, Ghanouni, Pejman, additional, Stein, Sherman, additional, Halpern, Casey, additional, Krishna, Vibhor, additional, Hargrove, Amelia, additional, Agrawal, Punit, additional, Changizi, Barbara, additional, Bourekas, Eric, additional, Knopp, Michael, additional, Rezai, Ali, additional, Mead, Brian, additional, Kim, Namho, additional, Mastorakos, Panagiotis, additional, Suk, Jung Soo, additional, Miller, Wilson, additional, Klibanov, Alexander, additional, Hanes, Justin, additional, Price, Richard, additional, Wang, Shutao, additional, Olumolade, Oluyemi, additional, Kugelman, Tara, additional, Jackson-Lewis, Vernice, additional, Karakatsani, Maria Eleni, additional, Han, Yang, additional, Przedborski, Serge, additional, Konofagou, Elisa, additional, Hynynen, Kullervo, additional, Aubert, Isabelle, additional, Leinenga, Gerhard, additional, Nisbet, Rebecca, additional, Hatch, Robert, additional, Van der Jeugd, Anneke, additional, Evans, Harrison, additional, Götz, Jürgen, additional, Van der Jeugd, Ann, additional, Fishman, Paul, additional, Yarowsky, Paul, additional, Frenkel, Victor, additional, Wei-Bin, Shen, additional, Nguyen, Ben, additional, Sanchez, Carlos Sierra, additional, Acosta, Camilo, additional, Chen, Cherry, additional, Wu, Shih-Ying, additional, Aryal, Muna, additional, Papademetriou, Iason T., additional, Zhang, Yong-Zhi, additional, Power, Chanikarn, additional, McDannold, Nathan, additional, Porter, Tyrone, additional, Kovacs, Zsofia, additional, Kim, Saejeong, additional, Jikaria, Neekita, additional, Qureshi, Farhan, additional, Bresler, Michele, additional, Frank, Joseph, additional, Odéen, Henrik, additional, Chiou, George, additional, Snell, John, additional, Todd, Nick, additional, Madore, Bruno, additional, Parker, Dennis, additional, Pauly, Kim Butts, additional, Marx, Mike, additional, Jonathan, Sumeeth, additional, Grissom, William, additional, Arvanitis, Costas, additional, Clement, Gregory, additional, de Bever, Joshua, additional, Payne, Allison, additional, Christensen, Douglas, additional, Maimbourg, Guillaume, additional, Santin, Mathieu David, additional, Houdouin, Alexandre, additional, Lehericy, Stéphane, additional, Tanter, Mickael, additional, Aubry, Jean Francois, additional, Federau, Christian, additional, Werner, Beat, additional, Paeng, Dong-Guk, additional, Xu, Zhiyuan, additional, Quigg, Anders, additional, Eames, Matt, additional, Jin, Changzhu, additional, Everstine, Ashli, additional, Sheehan, Jason, additional, Lopes, M. Beatriz, additional, Kassell, Neal, additional, Drake, James, additional, Price, Karl, additional, Lustgarten, Lior, additional, Sin, Vivian, additional, Mougenot, Charles, additional, Donner, Elizabeth, additional, Tam, Emily, additional, Hodaie, Mojgan, additional, Waspe, Adam, additional, Looi, Thomas, additional, Pichardo, Samuel, additional, Lee, Wonhye, additional, Chung, Yong An, additional, Jung, Yujin, additional, Song, In-Uk, additional, Yoo, Seung-Schik, additional, Kim, Hyun-Chul, additional, Lee, Jong-Hwan, additional, Caskey, Charles, additional, Zinke, Wolf, additional, Cosman, Josh, additional, Shuman, Jillian, additional, Schall, Jeffrey, additional, Aurup, Christian, additional, Chen, Hong, additional, Kamimura, Hermes, additional, Carneiro, Antonio, additional, Sun, Tao, additional, Nazai, Navid, additional, Patz, Sam, additional, Livingstone, Margaret, additional, Mainprize, Todd, additional, Huang, Yuexi, additional, Alkins, Ryan, additional, Chapman, Martin, additional, Perry, James, additional, Lipsman, Nir, additional, Bethune, Allison, additional, Sahgal, Arjun, additional, Trudeau, Maureen, additional, Liu, Hao-Li, additional, Hsu, Po-Hung, additional, Wei, Kuo-Chen, additional, Sutton, Jonathan, additional, Alexander, Phillip, additional, Miller, Eric, additional, Kobus, Thiele, additional, Carpentier, Alexandre, additional, Canney, Michael, additional, Vignot, Alexandre, additional, Beccaria, Kevin, additional, Leclercq, Delphine, additional, Lafon, Cyril, additional, Chapelon, Jean Yves, additional, Hoang-Xuan, Khe, additional, Delattre, Jean-Yves, additional, Idbaih, Ahmed, additional, Moore, David, additional, Xu, Alexis, additional, Schmitt, Paul, additional, Foley, Jessica, additional, Sukovich, Jonathan, additional, Cain, Charles, additional, Pandey, Aditya, additional, Chaudhary, Neeraj, additional, Camelo-Piragua, Sandra, additional, Allen, Steven, additional, Cannata, Jon, additional, Teofilovic, Dejan, additional, Bertolina, Jim, additional, Hall, Timothy, additional, Xu, Zhen, additional, Grondin, Julien, additional, Ferrera, Vincent, additional, ter Haar, Gail, additional, Mouratidis, Petros, additional, Repasky, Elizabeth, additional, Timbie, Kelsie, additional, Badr, Lena, additional, Campbell, Benjamin, additional, McMichael, John, additional, Buckner, Andrew, additional, Prince, Jessica, additional, Stevens, Aaron, additional, Bullock, Timothy, additional, Skalina, Karin, additional, Guha, Chandan, additional, Orsi, Franco, additional, Bonomo, Guido, additional, Vigna, Paolo Della, additional, Mauri, Giovanni, additional, Varano, Gianluca, additional, Schade, George, additional, Wang, Yak-Nam, additional, Pillarisetty, Venu, additional, Hwang, Joo Ha, additional, Khokhlova, Vera, additional, Bailey, Michael, additional, Khokhlova, Tatiana, additional, Sinilshchikov, Ilya, additional, Yuldashev, Petr, additional, Andriyakhina, Yulia, additional, Kreider, Wayne, additional, Maxwell, Adam, additional, Sapozhnikov, Oleg, additional, Partanen, Ari, additional, Lundt, Jonathan, additional, Preusser, Tobias, additional, Haase, Sabrina, additional, Bezzi, Mario, additional, Jenne, Jürgen, additional, Langø, Thomas, additional, Midiri, Massimo, additional, Mueller, Michael, additional, Sat, Giora, additional, Tanner, Christine, additional, Zangos, Stephan, additional, Guenther, Matthias, additional, Melzer, Andreas, additional, Menciassi, Arianna, additional, Tognarelli, Selene, additional, Cafarelli, Andrea, additional, Diodato, Alessandro, additional, Ciuti, Gastone, additional, Rothluebbers, Sven, additional, Schwaab, Julia, additional, Strehlow, Jan, additional, Mihcin, Senay, additional, Tretbar, Steffen, additional, Payen, Thomas, additional, Palermo, Carmine, additional, Sastra, Steve, additional, Olive, Kenneth, additional, Adams, Matthew, additional, Salgaonkar, Vasant, additional, Scott, Serena, additional, Sommer, Graham, additional, Diederich, Chris, additional, Vidal-Jove, Joan, additional, Perich, Eloi, additional, Ruiz, Antonio, additional, Velat, Manuela, additional, Melodelima, David, additional, Dupre, Aurelien, additional, Vincenot, Jeremy, additional, Yao, Chen, additional, Perol, David, additional, Rivoire, Michel, additional, Tucci, Samantha, additional, Mahakian, Lisa, additional, Fite, Brett, additional, Ingham, Elizabeth, additional, Tam, Sarah, additional, Hwang, Chang-il, additional, Tuveson, David, additional, Ferrara, Katherine, additional, Scionti, Stephen, additional, Chen, Lili, additional, Cvetkovic, Dusica, additional, Chen, Xiaoming, additional, Gupta, Roohi, additional, Wang, Bin, additional, Ma, Charlie, additional, Bader, Kenneth, additional, Haworth, Kevin, additional, Holland, Christy, additional, Sanghvi, Narendra, additional, Carlson, Roy, additional, Chen, Wohsing, additional, Chaussy, Christian, additional, Thueroff, Stefan, additional, Cesana, Claudio, additional, Bellorofonte, Carlo, additional, Wang, Qingguo, additional, Wang, Han, additional, Wang, Shengping, additional, Zhang, Junhai, additional, Bazzocchi, Alberto, additional, Napoli, Alessandro, additional, Staruch, Robert, additional, Bing, Chenchen, additional, Shaikh, Sumbul, additional, Nofiele, Joris, additional, Szczepanski, Debra, additional, Staruch, Michelle Wodzak, additional, Williams, Noelle, additional, Laetsch, Theodore, additional, Chopra, Rajiv, additional, Rosenberg, Jarrett, additional, Bitton, Rachelle, additional, LeBlang, Suzanne, additional, Meyer, Joshua, additional, Hurwitz, Mark, additional, Yarmolenko, Pavel, additional, Celik, Haydar, additional, Eranki, Avinash, additional, Beskin, Viktoriya, additional, Santos, Domiciano, additional, Patel, Janish, additional, Oetgen, Matthew, additional, Kim, AeRang, additional, Kim, Peter, additional, Sharma, Karun, additional, Chisholm, Alexander, additional, Aleman, Dionne, additional, Scipione, Roberto, additional, Temple, Michael, additional, Amaral, Joao Guilherme, additional, Endre, Ruby, additional, Lamberti-Pasculli, Maria, additional, de Ruiter, Joost, additional, Campbell, Fiona, additional, Stimec, Jennifer, additional, Gupta, Samit, additional, Singh, Manoj, additional, Hopyan, Sevan, additional, Czarnota, Gregory, additional, Brenin, David, additional, Rochman, Carrie, additional, Kovatcheva, Roussanka, additional, Vlahov, Jordan, additional, Zaletel, Katja, additional, Stoinov, Julian, additional, Bucknor, Matthew, additional, Rieke, Viola, additional, Shim, Jenny, additional, Koral, Korgun, additional, Lang, Brian, additional, Wong, Carlos, additional, Lam, Heather, additional, Shinkov, Alexander, additional, Hu, Jim, additional, Zhang, Xi, additional, Macoskey, Jonathan, additional, Ives, Kimberly, additional, Owens, Gabe, additional, Gurm, Hitinder, additional, Shi, Jiaqi, additional, Pizzuto, Matthew, additional, Dillon, Christopher, additional, Christofferson, Ivy, additional, Hilas, Elaine, additional, Shea, Jill, additional, Greillier, Paul, additional, Ankou, Bénédicte, additional, Bessière, Francis, additional, Zorgani, Ali, additional, Pioche, Mathieu, additional, Kwiecinski, Wojciech, additional, Magat, Julie, additional, Melot-Dusseau, Sandrine, additional, Lacoste, Romain, additional, Quesson, Bruno, additional, Pernot, Mathieu, additional, Catheline, Stefan, additional, Chevalier, Philippe, additional, Marquet, Fabrice, additional, Bour, Pierre, additional, Vaillant, Fanny, additional, Amraoui, Sana, additional, Dubois, Rémi, additional, Ritter, Philippe, additional, Haïssaguerre, Michel, additional, Hocini, Mélèze, additional, Bernus, Olivier, additional, Tebebi, Pamela, additional, Burks, Scott, additional, Milo, Blerta, additional, Gertner, Michael, additional, Zhang, Jimin, additional, Wong, Andrew, additional, Liu, Yu, additional, Kheirolomoom, Azadeh, additional, Seo, Jai, additional, Watson, Katherine, additional, Zhang, Hua, additional, Foiret, Josquin, additional, Borowsky, Alexander, additional, Xu, Doudou, additional, Thanou, Maya, additional, Centelles, Miguell, additional, Wright, Mike, additional, Amrahli, Maral, additional, So, Po-Wah, additional, Gedroyc, Wladyslaw, additional, Kneepkens, Esther, additional, Heijman, Edwin, additional, Keupp, Jochen, additional, Weiss, Steffen, additional, Nicolay, Klaas, additional, Grüll, Holger, additional, Nagle, Matthew, additional, Nikolaeva, Anastasia V., additional, Terzi, Marina E., additional, Tsysar, Sergey A., additional, Cunitz, Bryan, additional, Mourad, Pierre, additional, Downs, Matthew, additional, Yang, Georgiana, additional, Wang, Qi, additional, Chen, Johnny, additional, Farry, Justin, additional, Dixon, Adam, additional, Du, Zhongmin, additional, Dhanaliwala, Ali, additional, Hossack, John, additional, Ranjan, Ashish, additional, Maples, Danny, additional, Wardlow, Rachel, additional, Malayer, Jerry, additional, Ramachandran, Akhilesh, additional, Namba, Hirofumi, additional, Kawasaki, Motohiro, additional, Izumi, Masashi, additional, Kiyasu, Katsuhito, additional, Takemasa, Ryuichi, additional, Ikeuchi, Masahiko, additional, Ushida, Takahiro, additional, Crake, Calum, additional, Kothapalli, Satya V. V. N., additional, Leighton, Wan, additional, Wang, Zhaorui, additional, Gach, H. Michael, additional, Straube, William, additional, Altman, Michael, additional, Kim, Young-sun, additional, Lim, Hyo Keun, additional, Rhim, Hyunchul, additional, van Breugel, Johanna, additional, Braat, Manon, additional, Moonen, Chrit, additional, van den Bosch, Maurice, additional, Ries, Mario, additional, Marrocchio, Cristina, additional, Dababou, Susan, additional, Lee, Jae Young, additional, Chung, Hyun Hoon, additional, Kang, Soo Yeon, additional, Kang, Kook Jin, additional, Son, Keon Ho, additional, Zhang, Dandan, additional, Plata, Juan, additional, Jones, Peter, additional, Pascal-Tenorio, Aurea, additional, Bouley, Donna, additional, Bond, Aaron, additional, Dallapiazza, Robert, additional, Huss, Diane, additional, Warren, Amy, additional, Sperling, Scott, additional, Gwinn, Ryder, additional, Shah, Binit, additional, Elias, W. Jeff, additional, Curley, Colleen, additional, Zhang, Ying, additional, Negron, Karina, additional, Abounader, Roger, additional, Samiotaki, Gesthimani, additional, Tu, Tsang-Wei, additional, Papadakis, Georgios, additional, Hammoud, Dima, additional, Silvestrini, Matthew, additional, Wolfram, Frank, additional, Güllmar, Daniel, additional, Reichenbach, Juergen, additional, Hofmann, Denis, additional, Böttcher, Joachim, additional, Schubert, Harald, additional, Lesser, Thomas G., additional, Almquist, Scott, additional, Camarena, Francisco, additional, Jiménez-Gambín, Sergio, additional, Jiménez, Noé, additional, Chang, Jin Woo, additional, Chaplin, Vandiver, additional, Griesenauer, Rebekah, additional, Miga, Michael, additional, Ellens, Nicholas, additional, Airan, Raag, additional, Quinones-Hinojosa, Alfredo, additional, Farahani, Keyvan, additional, Feng, Xue, additional, Fielden, Samuel, additional, Zhao, Li, additional, Wintermark, Max, additional, Meyer, Craig, additional, Guo, Sijia, additional, Lu, Xin, additional, Zhuo, Jiachen, additional, Xu, Su, additional, Gullapalli, Rao, additional, Gandhi, Dheeraj, additional, Brokman, Omer, additional, Baek, Hongchae, additional, Kim, Hyungmin, additional, Leung, Steven, additional, Webb, Taylor, additional, Vykhodtseva, Natalia, additional, Nguyen, Thai-Son, additional, Park, Chang Kyu, additional, Park, Sang Man, additional, Jung, Na Young, additional, Kim, Min Soo, additional, Chang, Won Seok, additional, Jung, Hyun Ho, additional, Plaksin, Michael, additional, Weissler, Yoni, additional, Shoham, Shy, additional, Kimmel, Eitan, additional, Rosnitskiy, Pavel B., additional, Krupa, Steve, additional, Hazan, Eilon, additional, Naor, Omer, additional, Levy, Yoav, additional, Maimon, Noam, additional, Brosh, Inbar, additional, Kahn, Itamar, additional, Cahill, Jessica, additional, Colas, Elodie Constanciel, additional, Wydra, Adrian, additional, Maev, Roman, additional, Aly, Amirah, additional, Sesenoglu-Laird, Ozge, additional, Padegimas, Linas, additional, Cooper, Mark, additional, Waszczak, Barbara, additional, Tehrani, Seruz, additional, Slingluff, Craig, additional, Larner, James, additional, Andarawewa, Kumari, additional, Ozhinsky, Eugene, additional, Shah, Rutwik, additional, Krug, Roland, additional, Deckers, Roel, additional, Linn, Sabine, additional, Suelmann, Britt, additional, Witkamp, Arjen, additional, Vaessen, Paul, additional, van Diest, Paul, additional, Bartels, Lambertus W., additional, Bos, Clemens, additional, Borys, Nicolas, additional, Storm, Gert, additional, Van der Wall, Elsken, additional, Farr, Navid, additional, Alnazeer, Moez, additional, Katti, Prateek, additional, Wood, Bradford, additional, Farrer, Alexis, additional, Ferrer, Cyril, additional, de Senneville, Baudouin Denis, additional, van Stralen, Marijn, additional, Liu, Jingfei, additional, Leach, J. Kent, additional, Zidowitz, Stephan, additional, Lee, Hsin-Lun, additional, Hsu, Fang-Chi, additional, Kuo, Chia-Chun, additional, Jeng, Shiu-Chen, additional, Chen, Tung-Ho, additional, Yang, Nai-Yi, additional, Chiou, Jeng-Fong, additional, Kao, Yi-tzu, additional, Pan, Chia-Hsin, additional, Wu, Jing-Fu, additional, Tsai, Yi-Chieh, additional, Johnson, Sara, additional, Li, Dawei, additional, He, Ye, additional, Karakitsios, Ioannis, additional, Schwenke, Michael, additional, Demedts, Daniel, additional, Xiao, Xu, additional, Cavin, Ian, additional, Minalga, Emilee, additional, Merrill, Robb, additional, Hadley, Rock, additional, Ramaekers, Pascal, additional, de Greef, Martijn, additional, Shahriari, Kian, additional, Parvizi, Mohammad Hossein, additional, Asadnia, Kiana, additional, Chamanara, Marzieh, additional, Kamrava, Seyed Kamran, additional, Chabok, Hamid Reza, additional, Stein, Ruben, additional, Muller, Sébastien, additional, Tan, Jeremy, additional, Zachiu, Cornel, additional, Erasmus, Hans-Peter, additional, Van Arsdell, Glen, additional, Benson, Lee, additional, Jang, Kee W., additional, Angstadt, Mary, additional, Lewis, Bobbi, additional, McLean, Hailey, additional, Hoogenboom, Martijn, additional, Eikelenboom, Dylan, additional, den Brok, Martijn, additional, Wesseling, Pieter, additional, Heerschap, Arend, additional, Fütterer, Jurgen, additional, Adema, Gosse, additional, Wang, Kevin, additional, Zhong, Pei, additional, Joy, Joyce, additional, McLeod, Helen, additional, Kim, Harry, additional, Lewis, Matthew, additional, Ozilgen, Arda, additional, Zahos, Peter, additional, Coughlin, Dezba, additional, Tang, Xinyan, additional, Lotz, Jeff, additional, Jedruszczuk, Kathleen, additional, Gulati, Amitabh, additional, Solomon, Stephen, additional, Kaye, Elena, additional, Mugler, John, additional, Barbato, Gaetano, additional, Scoarughi, Gian Luca, additional, Corso, Cristiano, additional, Gorgone, Alessandro, additional, Migliore, Ilaria Giuseppina, additional, Larrabee, Zachary, additional, Hananel, Arik, additional, Aubry, Jean-Francois, additional, Negussie, Ayele, additional, Wilson, Emmanuel, additional, Seifabadi, Reza, additional, Moon, Hyungwon, additional, Kang, Jeeun, additional, Sim, Changbeom, additional, Chang, Jin Ho, additional, Kim, Hyuncheol, additional, Lee, Hak Jong, additional, Sasaki, Noboru, additional, Takiguchi, Mitsuyoshi, additional, Sebeke, Lukas, additional, Luo, Xi, additional, de Jager, Bram, additional, Heemels, Maurice, additional, Abraham, Christopher, additional, Curiel, Laura, additional, Berriet, Rémi, additional, Janát-Amsbury, Margit, additional, Corea, Joseph, additional, Ye, Patrick Peiyong, additional, Arias, Ana Clauda, additional, Lustig, Micheal, additional, and Svedin, Bryant, additional

Published

2016

38. Cycad-induced Neurodegeneration Is Different in Rat and Mouse Models of ALS-PDC

Author

Paul J. Yarowsky, Kimberly A. McDowell, Christopher A. Shaw, R. Cruz-Aguado, Wei-Bin Shen, Thomas E. Marler, and J. M. B. Wilson

Subjects

biology, Neurodegeneration, medicine, Dementia, biology.organism_classification, medicine.disease, Cycad, Neuroscience

Published

2012

39. Induction of neural differentiation by the transcription factor neuroD2

Author

Wei-Bin Shen, Kirsten Messmer, Mary P. Remington, and Paul S. Fishman

Subjects

Cell type, Cellular differentiation, Neurogenesis, Primary Cell Culture, Nerve Tissue Proteins, Biology, Neurogenins, Synaptotagmin 1, Mice, Neuroblastoma, Developmental Neuroscience, Neural Stem Cells, Cell Line, Tumor, Basic Helix-Loop-Helix Transcription Factors, Animals, Humans, Progenitor cell, Helix-Turn-Helix Motifs, HEK 293 cells, Neuropeptides, Cell Differentiation, Neural stem cell, Cell biology, Rats, HEK293 Cells, nervous system, Synapses, Stem cell, Developmental Biology

Abstract

Pro-neural basic helix loop helix (bHLH) transcription factors are involved in many aspects of normal neuronal development, and over-expression of genes for several of these factors has been shown to induce aspects of neuronal differentiation in cell lines and stem cells. Here we show that over-expression of NeuroD2 (ND2), Neurogenin1 and 2 leads to morphological differentiation of N18-RE-105 neuroblastoma cells and increased expression of synaptic proteins. Particularly ND2 induced neurite formation and increases in the expression of synaptic proteins such as synaptotagmin, that is not expressed normally in this cell type, as well as the redistribution of another synaptic protein, SNAP25, to a cell membrane location. Infection of human neural progenitor cells using adeno associated viral (AAV) vectors also promoted neuronal differentiation. Over-expressing cells demonstrated a significant increase in the neuron specific form of tubulin as well as increased expression of synaptotagmin. Genetic modification of neural progenitor cell with bHLH factors such as ND2 may be a viable strategy to enhance differentiation of these cells into replacement neurons for human disease.

Published

2011

40. Imaging, anatomical, and molecular analysis of callosal formation in the developing human fetal brain

Author

Hao Huang, Wei-Bin Shen, Aurora Anderson, Tianbo Ren, Jiangyang Zhang, Susumu Mori, Celine Plachez, Linda J. Richards, and Stephen L. Kinsman

Subjects

Anterior commissure, Human brain, Anatomy, Commissure, Biology, medicine.disease, Corpus callosum, Blotting, Northern, Agricultural and Biological Sciences (miscellaneous), Slit, Hippocampus, Magnetic Resonance Imaging, Axons, Corpus Callosum, Immunoenzyme Techniques, medicine.anatomical_structure, Fetus, nervous system, Forebrain, medicine, Humans, Axon guidance, Agenesis of the corpus callosum, Biomarkers

Abstract

A complex set of axonal guidance mechanisms are utilized by axons to locate and innervate their targets. In the developing mouse forebrain, we previously described several midline glial populations as well as various guidance molecules that regulate the formation of the corpus callosum. Since agenesis of the corpus callosum is associated with over 50 different human congenital syndromes, we wanted to investigate whether these same mechanisms also operate during human callosal development. Here we analyze midline glial and commissural development in human fetal brains ranging from 13 to 20 weeks of gestation using both diffusion tensor magnetic resonance imaging and immunohistochemistry. Through our combined radiological and histological studies, we demonstrate the morphological development of multiple forebrain commissures/decussations, including the corpus callosum, anterior commissure, hippocampal commissure, and the optic chiasm. Histological analyses demonstrated that all the midline glial populations previously described in mouse, as well as structures analogous to the subcallosal sling and cingulate pioneering axons, that mediate callosal axon guidance in mouse, are also present during human brain development. Finally, by Northern blot analysis, we have identified that molecules involved in mouse callosal development, including Slit, Robo, Netrin1, DCC, Nfia, Emx1, and GAP-43, are all expressed in human fetal brain. These data suggest that similar mechanisms and molecules required for midline commissure formation operate during both mouse and human brain development. Thus, the mouse is an excellent model system for studying normal and pathological commissural formation in human brain development. © 2006 Wiley-Liss, Inc.

Published

2006

41. Reply

Author

Kimberly A. McDowell, Wei-Bin Shen, Aubrey A. Siebert, Sarah M. Clark, H.A. Jinnah, Carole Sztalryd, Paul S. Fishman, Christopher A. Shaw, M. Samir Jafri, and Paul J. Yarowsky

Subjects

Neurology, Neurology (clinical)

Published

2011

42. Development of the perforating pathway: an ipsilaterally projecting pathway between the medial septum/diagonal band of Broca and the cingulate cortex that intersects the corpus callosum

Author

Wei-Bin Shen, Linda J. Richards, and Tianzhi Shu

Subjects

Cingulate cortex, Nervous system, Cell Count, Biology, Corpus callosum, Corpus Callosum, Mice, Neural Pathways, medicine, Animals, Cerebral Cortex, Basal forebrain, Brain Mapping, Neocortex, General Neuroscience, Anatomy, Immunohistochemistry, Diagonal band of Broca, Axons, Frontal Lobe, Mice, Inbred C57BL, medicine.anatomical_structure, nervous system, Cerebral cortex, Axon guidance, Septum of Brain, Neuroscience

Abstract

The perforating pathway (PFP) intersects the corpus callosum perpendicularly at the midline in the dorsoventral axis. Therefore axons in either the PFP or the corpus callosum make different axonal guidance decisions in the same anatomical region of the developing cortical midline. The mechanisms underlying these axonal choices are not known. To begin to identify these guidance mechanisms, we characterized the development of these two pathways in detail. The development of the corpus callosum and its pioneering projections has been described elsewhere (Shu and Richards [2001] J. Neurosci. 21:2749--2758; Rash and Richards [2001] J. Comp. Neurol. 434:147--157). Here we examine the development, origins, and projections of axons that make up the PFP. The majority of axons within the PFP originate from neurons in the medial septum and diagonal band of Broca complex. These neurons project in a topographic manner to the cingulate cortex. In contrast to previous reports, we find that a much smaller projection originating from the cingulate cortex also contributes to this pathway. The pioneering projections of the PFP and the corpus callosum arrive at the corticoseptal boundary at around the same developmental stage. These findings show that ipsilaterally projecting PFP axons and contralaterally projecting callosal axons make distinct guidance decisions at the same developmental stage when they reach the corticoseptal boundary.

Published

2001

43. Purification of a gonadotropin-releasing hormone-like peptide in human early placenta

Author

Chong-Li Zhang, Wei-Bin Shen, Ai-Min Zou, Hong Yin, Jean Rivier, and Charlean Miller

Subjects

chemistry.chemical_classification, medicine.medical_specialty, medicine.anatomical_structure, Endocrinology, chemistry, Internal medicine, Placenta, medicine, Peptide, Gonadotropin-releasing hormone

Published

1995

44. Reply

Author

Kimberly A. McDowell, Wei-Bin Shen, Aubrey A. Siebert, Sarah M. Clark, H.A. Jinnah, Carole Sztalryd, Paul S. Fishman, Christopher A. Shaw, M. Samir Jafri, and Paul J. Yarowsky

Subjects

Neurology, Neurology (clinical)

Published

2010

45. Human neural progenitor cells retain viability, phenotype, proliferation, and lineage differentiation when labeled with a novel iron oxide nanoparticle, Molday ION Rhodamine B.

Author

Wei-Bin Shen, Plachez, Celine, Chan, Amanda, Yarnell, Deborah, Puche, Adam C., Fishman, Paul S., and Yarowsky, Paul

Published

2013

46. Imaging, anatomical, and molecular analysis of callosal formation in the developing human fetal brain.

Author

Tianbo Ren, Aurora Anderson, Wei‐Bin Shen, Hao Huang, Celine Plachez, Jiangyang Zhang, Susumu Mori, Stephen L. Kinsman, and Linda J. Richards

Published

2006

47. 5th International Symposium on Focused Ultrasound

Author

Zaaroor, Menashe, Sinai, Alon, Goldsher, Dorit, Eran, Ayelet, Nassar, Maria, Schlesinger, Ilana, Parker, Jonathon, Ravikumar, Vinod, Ghanouni, Pejman, Stein, Sherman, Halpern, Casey, Krishna, Vibhor, Hargrove, Amelia, Agrawal, Punit, Changizi, Barbara, Bourekas, Eric, Knopp, Michael, Rezai, Ali, Mead, Brian, Kim, Namho, Mastorakos, Panagiotis, Suk, Jung Soo, Miller, Wilson, Klibanov, Alexander, Hanes, Justin, Price, Richard, Wang, Shutao, Olumolade, Oluyemi, Kugelman, Tara, Jackson-Lewis, Vernice, Karakatsani, Maria Eleni (Marilena), Han, Yang, Przedborski, Serge, Konofagou, Elisa, Hynynen, Kullervo, Aubert, Isabelle, Leinenga, Gerhard, Nisbet, Rebecca, Hatch, Robert, Van der Jeugd, Anneke, Evans, Harrison, Götz, Jürgen, Van der Jeugd, Ann, Fishman, Paul, Yarowsky, Paul, Frenkel, Victor, Wei-Bin, Shen, Nguyen, Ben, Sanchez, Carlos Sierra, Acosta, Camilo, Chen, Cherry, Wu, Shih-Ying, Aryal, Muna, Papademetriou, Iason T., Zhang, Yong-Zhi, Power, Chanikarn, McDannold, Nathan, Porter, Tyrone, Kovacs, Zsofia, Kim, Saejeong, Jikaria, Neekita, Qureshi, Farhan, Bresler, Michele, Frank, Joseph, Odéen, Henrik, Chiou, George, Snell, John, Todd, Nick, Madore, Bruno, Parker, Dennis, Pauly, Kim Butts, Marx, Mike, Jonathan, Sumeeth, Grissom, William, Arvanitis, Costas, Clement, Gregory, de Bever, Joshua, Payne, Allison, Christensen, Douglas, Maimbourg, Guillaume, Santin, Mathieu David, Houdouin, Alexandre, Lehericy, Stéphane, Tanter, Mickael, Aubry, Jean Francois, Federau, Christian, Werner, Beat, Paeng, Dong-Guk, Xu, Zhiyuan, Quigg, Anders, Eames, Matt, Jin, Changzhu, Everstine, Ashli, Sheehan, Jason, Lopes, M. Beatriz, Kassell, Neal, Drake, James, Price, Karl, Lustgarten, Lior, Sin, Vivian, Mougenot, Charles, Donner, Elizabeth, Tam, Emily, Hodaie, Mojgan, Waspe, Adam, Looi, Thomas, Pichardo, Samuel, Lee, Wonhye, Chung, Yong An, Jung, Yujin, Song, In-Uk, Yoo, Seung-Schik, Kim, Hyun-Chul, Lee, Jong-Hwan, Caskey, Charles, Zinke, Wolf, Cosman, Josh, Shuman, Jillian, Schall, Jeffrey, Aurup, Christian, Chen, Hong, Kamimura, Hermes, Carneiro, Antonio, Sun, Tao, Nazai, Navid, Patz, Sam, Livingstone, Margaret, Mainprize, Todd, Huang, Yuexi, Alkins, Ryan, Chapman, Martin, Perry, James, Lipsman, Nir, Bethune, Allison, Sahgal, Arjun, Trudeau, Maureen, Liu, Hao-Li, Hsu, Po-Hung, Wei, Kuo-Chen, Sutton, Jonathan, Alexander, Phillip, Miller, Eric, Kobus, Thiele, Carpentier, Alexandre, Canney, Michael, Vignot, Alexandre, Beccaria, Kevin, Leclercq, Delphine, Lafon, Cyril, Chapelon, Jean Yves, Hoang-Xuan, Khe, Delattre, Jean-Yves, Idbaih, Ahmed, Moore, David, Xu, Alexis, Schmitt, Paul, Foley, Jessica, Sukovich, Jonathan, Cain, Charles, Pandey, Aditya, Chaudhary, Neeraj, Camelo-Piragua, Sandra, Allen, Steven, Cannata, Jon, Teofilovic, Dejan, Bertolina, Jim, Hall, Timothy, Xu, Zhen, Grondin, Julien, Ferrera, Vincent, ter Haar, Gail, Mouratidis, Petros, Repasky, Elizabeth, Timbie, Kelsie, Badr, Lena, Campbell, Benjamin, McMichael, John, Buckner, Andrew, Prince, Jessica, Stevens, Aaron, Bullock, Timothy, Skalina, Karin, Guha, Chandan, Orsi, Franco, Bonomo, Guido, Vigna, Paolo Della, Mauri, Giovanni, Varano, Gianluca, Schade, George, Wang, Yak-Nam, Pillarisetty, Venu, Hwang, Joo Ha, Khokhlova, Vera, Bailey, Michael, Khokhlova, Tatiana, Sinilshchikov, Ilya, Yuldashev, Petr, Andriyakhina, Yulia, Kreider, Wayne, Maxwell, Adam, Sapozhnikov, Oleg, Partanen, Ari, Lundt, Jonathan, Preusser, Tobias, Haase, Sabrina, Bezzi, Mario, Jenne, Jürgen, Langø, Thomas, Midiri, Massimo, Mueller, Michael, Sat, Giora, Tanner, Christine, Zangos, Stephan, Guenther, Matthias, Melzer, Andreas, Menciassi, Arianna, Tognarelli, Selene, Cafarelli, Andrea, Diodato, Alessandro, Ciuti, Gastone, Rothluebbers, Sven, Schwaab, Julia, Strehlow, Jan, Mihcin, Senay, Tretbar, Steffen, Payen, Thomas, Palermo, Carmine, Sastra, Steve, Olive, Kenneth, Adams, Matthew, Salgaonkar, Vasant, Scott, Serena, Sommer, Graham, Diederich, Chris, Vidal-Jove, Joan, Perich, Eloi, Ruiz, Antonio, Velat, Manuela, Melodelima, David, Dupre, Aurelien, Vincenot, Jeremy, Yao, Chen, Perol, David, Rivoire, Michel, Tucci, Samantha, Mahakian, Lisa, Fite, Brett, Ingham, Elizabeth, Tam, Sarah, Hwang, Chang-il, Tuveson, David, Ferrara, Katherine, Scionti, Stephen, Chen, Lili, Cvetkovic, Dusica, Chen, Xiaoming, Gupta, Roohi, Wang, Bin, Ma, Charlie, Bader, Kenneth, Haworth, Kevin, Holland, Christy, Sanghvi, Narendra, Carlson, Roy, Chen, Wohsing, Chaussy, Christian, Thueroff, Stefan, Cesana, Claudio, Bellorofonte, Carlo, Wang, Qingguo, Wang, Han, Wang, Shengping, Zhang, Junhai, Bazzocchi, Alberto, Napoli, Alessandro, Staruch, Robert, Bing, Chenchen, Shaikh, Sumbul, Nofiele, Joris, Szczepanski, Debra, Staruch, Michelle Wodzak, Williams, Noelle, Laetsch, Theodore, Chopra, Rajiv, Rosenberg, Jarrett, Bitton, Rachelle, LeBlang, Suzanne, Meyer, Joshua, Hurwitz, Mark, Yarmolenko, Pavel, Celik, Haydar, Eranki, Avinash, Beskin, Viktoriya, Santos, Domiciano, Patel, Janish, Oetgen, Matthew, Kim, AeRang, Kim, Peter, Sharma, Karun, Chisholm, Alexander, Aleman, Dionne, Scipione, Roberto, Temple, Michael, Amaral, Joao Guilherme, Endre, Ruby, Lamberti-Pasculli, Maria, de Ruiter, Joost, Campbell, Fiona, Stimec, Jennifer, Gupta, Samit, Singh, Manoj, Hopyan, Sevan, Czarnota, Gregory, Brenin, David, Rochman, Carrie, Kovatcheva, Roussanka, Vlahov, Jordan, Zaletel, Katja, Stoinov, Julian, Bucknor, Matthew, Rieke, Viola, Shim, Jenny, Koral, Korgun, Lang, Brian, Wong, Carlos, Lam, Heather, Shinkov, Alexander, Hu, Jim, Zhang, Xi, Macoskey, Jonathan, Ives, Kimberly, Owens, Gabe, Gurm, Hitinder, Shi, Jiaqi, Pizzuto, Matthew, Dillon, Christopher, Christofferson, Ivy, Hilas, Elaine, Shea, Jill, Greillier, Paul, Ankou, Bénédicte, Bessière, Francis, Zorgani, Ali, Pioche, Mathieu, Kwiecinski, Wojciech, Magat, Julie, Melot-Dusseau, Sandrine, Lacoste, Romain, Quesson, Bruno, Pernot, Mathieu, Catheline, Stefan, Chevalier, Philippe, Marquet, Fabrice, Bour, Pierre, Vaillant, Fanny, Amraoui, Sana, Dubois, Rémi, Ritter, Philippe, Haïssaguerre, Michel, Hocini, Mélèze, Bernus, Olivier, Tebebi, Pamela, Burks, Scott, Milo, Blerta, Gertner, Michael, Zhang, Jimin, Wong, Andrew, Liu, Yu, Kheirolomoom, Azadeh, Seo, Jai, Watson, Katherine, Zhang, Hua, Foiret, Josquin, Borowsky, Alexander, Xu, Doudou, Thanou, Maya, Centelles, Miguell, Wright, Mike, Amrahli, Maral, So, Po-Wah, Gedroyc, Wladyslaw, Kneepkens, Esther, Heijman, Edwin, Keupp, Jochen, Weiss, Steffen, Nicolay, Klaas, Grüll, Holger, Nagle, Matthew, Nikolaeva, Anastasia V., Terzi, Marina E., Tsysar, Sergey A., Cunitz, Bryan, Mourad, Pierre, Downs, Matthew, Yang, Georgiana, Wang, Qi, Chen, Johnny, Farry, Justin, Dixon, Adam, Du, Zhongmin, Dhanaliwala, Ali, Hossack, John, Ranjan, Ashish, Maples, Danny, Wardlow, Rachel, Malayer, Jerry, Ramachandran, Akhilesh, Namba, Hirofumi, Kawasaki, Motohiro, Izumi, Masashi, Kiyasu, Katsuhito, Takemasa, Ryuichi, Ikeuchi, Masahiko, Ushida, Takahiro, Crake, Calum, Kothapalli, Satya V. V. N., Leighton, Wan, Wang, Zhaorui, Gach, H. Michael, Straube, William, Altman, Michael, Kim, Young-sun, Lim, Hyo Keun, Rhim, Hyunchul, van Breugel, Johanna, Braat, Manon, Moonen, Chrit, van den Bosch, Maurice, Ries, Mario, Marrocchio, Cristina, Dababou, Susan, Lee, Jae Young, Chung, Hyun Hoon, Kang, Soo Yeon, Kang, Kook Jin, Son, Keon Ho, Zhang, Dandan, Plata, Juan, Jones, Peter, Pascal-Tenorio, Aurea, Bouley, Donna, Bond, Aaron, Dallapiazza, Robert, Huss, Diane, Warren, Amy, Sperling, Scott, Gwinn, Ryder, Shah, Binit, Elias, W. Jeff, Curley, Colleen, Zhang, Ying, Negron, Karina, Abounader, Roger, Samiotaki, Gesthimani, Tu, Tsang-Wei, Papadakis, Georgios, Hammoud, Dima, Silvestrini, Matthew, Wolfram, Frank, Güllmar, Daniel, Reichenbach, Juergen, Hofmann, Denis, Böttcher, Joachim, Schubert, Harald, Lesser, Thomas G., Almquist, Scott, Camarena, Francisco, Jiménez-Gambín, Sergio, Jiménez, Noé, Chang, Jin Woo, Chaplin, Vandiver, Griesenauer, Rebekah, Miga, Michael, Ellens, Nicholas, Airan, Raag, Quinones-Hinojosa, Alfredo, Farahani, Keyvan, Feng, Xue, Fielden, Samuel, Zhao, Li, Wintermark, Max, Meyer, Craig, Guo, Sijia, Lu, Xin, Zhuo, Jiachen, Xu, Su, Gullapalli, Rao, Gandhi, Dheeraj, Brokman, Omer, Baek, Hongchae, Kim, Hyungmin, Leung, Steven, Webb, Taylor, Vykhodtseva, Natalia, Nguyen, Thai-Son, Park, Chang Kyu, Park, Sang Man, Jung, Na Young, Kim, Min Soo, Chang, Won Seok, Jung, Hyun Ho, Plaksin, Michael, Weissler, Yoni, Shoham, Shy, Kimmel, Eitan, Rosnitskiy, Pavel B., Krupa, Steve, Hazan, Eilon, Naor, Omer, Levy, Yoav, Maimon, Noam, Brosh, Inbar, Kahn, Itamar, Cahill, Jessica, Colas, Elodie Constanciel, Wydra, Adrian, Maev, Roman, Aly, Amirah, Sesenoglu-Laird, Ozge, Padegimas, Linas, Cooper, Mark, Waszczak, Barbara, Tehrani, Seruz, Slingluff, Craig, Larner, James, Andarawewa, Kumari, Ozhinsky, Eugene, Shah, Rutwik, Krug, Roland, Deckers, Roel, Linn, Sabine, Suelmann, Britt, Witkamp, Arjen, Vaessen, Paul, van Diest, Paul, Bartels, Lambertus W., Bos, Clemens, Borys, Nicolas, Storm, Gert, Van der Wall, Elsken, Farr, Navid, Alnazeer, Moez, Katti, Prateek, Wood, Bradford, Farrer, Alexis, Ferrer, Cyril, de Senneville, Baudouin Denis, van Stralen, Marijn, Liu, Jingfei, Leach, J. Kent, Zidowitz, Stephan, Lee, Hsin-Lun, Hsu, Fang-Chi, Kuo, Chia-Chun, Jeng, Shiu-Chen, Chen, Tung-Ho, Yang, Nai-Yi, Chiou, Jeng-Fong, Kao, Yi-tzu, Pan, Chia-Hsin, Wu, Jing-Fu, Tsai, Yi-Chieh, Johnson, Sara, Li, Dawei, He, Ye, Karakitsios, Ioannis, Schwenke, Michael, Demedts, Daniel, Xiao, Xu, Cavin, Ian, Minalga, Emilee, Merrill, Robb, Hadley, Rock, Ramaekers, Pascal, de Greef, Martijn, Shahriari, Kian, Parvizi, Mohammad Hossein, Asadnia, Kiana, Chamanara, Marzieh, Kamrava, Seyed Kamran, Chabok, Hamid Reza, Stein, Ruben, Muller, Sébastien, Tan, Jeremy, Zachiu, Cornel, Erasmus, Hans-Peter, Van Arsdell, Glen, Benson, Lee, Jang, Kee W., Angstadt, Mary, Lewis, Bobbi, McLean, Hailey, Hoogenboom, Martijn, Eikelenboom, Dylan, den Brok, Martijn, Wesseling, Pieter, Heerschap, Arend, Fütterer, Jurgen, Adema, Gosse, Wang, Kevin, Zhong, Pei, Joy, Joyce, McLeod, Helen, Kim, Harry, Lewis, Matthew, Ozilgen, Arda, Zahos, Peter, Coughlin, Dezba, Tang, Xinyan, Lotz, Jeff, Jedruszczuk, Kathleen, Gulati, Amitabh, Solomon, Stephen, Kaye, Elena, Mugler, John, Barbato, Gaetano, Scoarughi, Gian Luca, Corso, Cristiano, Gorgone, Alessandro, Migliore, Ilaria Giuseppina, Larrabee, Zachary, Hananel, Arik, Aubry, Jean-Francois, Negussie, Ayele, Wilson, Emmanuel, Seifabadi, Reza, Moon, Hyungwon, Kang, Jeeun, Sim, Changbeom, Chang, Jin Ho, Kim, Hyuncheol, Lee, Hak Jong, Sasaki, Noboru, Takiguchi, Mitsuyoshi, Sebeke, Lukas, Luo, Xi, de Jager, Bram, Heemels, Maurice, Abraham, Christopher, Curiel, Laura, Berriet, Rémi, Janát-Amsbury, Margit, Corea, Joseph, Ye, Patrick Peiyong, Arias, Ana Clauda, Lustig, Micheal, and Svedin, Bryant

Subjects

lcsh:Medical physics. Medical radiology. Nuclear medicine, Fibroadenomata, Cryo-ablation, High-intensity focused ultrasound, Ablative techniques, lcsh:R895-920, Review, Meeting Abstracts, Laser ablation

Abstract

Introduction Breast fibroadenomata (FAD) are benign lesions which occur in about 10 % of all women. Diagnosis is made by triple assessment (physical examination, imaging and/or histopathology/cytology). For a definitive diagnosis of FAD, the treatment is conservative unless the patient is symptomatic. For symptomatic patients, the lumps can be surgically excised or removed interventionally by vacuum-assisted mammotomy (VAM). Ablative techniques like high-intensity focused ultrasound (HIFU), cryo-ablation and laser ablation have also been used for the treatment of FAD, providing a minimally invasive treatment without scarring or poor cosmesis. This review summarises current trials using minimally invasive ablative techniques in the treatment of breast FAD. Methods A comprehensive review of studies using minimally invasive ablative techniques was performed. Results There are currently several trials completed or recruiting patients using HIFU, cryo-ablation and laser ablation in the treatment of breast FAD. The results look very promising but cannot be compared at this point due to heterogeneity between studies. Conclusion Minimally invasive ablative techniques like HIFU, cryo-ablation and laser ablation are promising in the treatment of breast FAD. Future trials should be randomised and contain larger numbers of patients to determine the effectiveness of ablative techniques with more precision.

48. Reply.

Author

McDowell, Kimberly A., Wei-Bin Shen, Siebert, Aubrey A., Clark, Sarah M., Jinnah, H. A., Sztalryd, Carole, Fishman, Paul S., Shaw, Christopher A., Jafri, M. Samir, and Yarowsky, Paul J.

Subjects

*LETTERS to the editor, *PARKINSON'S disease

Abstract

A response by Kimberly A. McDowell and colleagues to a letter to the editor related to association of b-Methylamino-L-alanine (BMAA) and Parkinson's disease in a previous issue is presented.

Published

2011